Radiographic image capturing apparatus and method for supplying electric power thereto

ABSTRACT

A radiographic image capturing apparatus includes a mobile cart unit, a plurality of devices used for capturing a radiographic image, and an electric power supply activator enabling supply of electric power between the devices, based on an instruction of permission to supply electric power.

CROSS-REFERENCE TO RELATED APPLICATION

This application is based upon and claims the benefit of priority from Japanese Patent Applications No. 2010-148329 filed on Jun. 29, 2010, No. 2010-148342 filed on Jun. 29, 2010 and No. 2010-150471 filed on Jun. 30, 2010, of which the contents are incorporated herein by reference.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a radiographic image capturing apparatus, which includes a radiation source and a radiation detector required for capturing radiographic images, and which can be carried to, e.g., a patient in order to obtain radiographic image information of the patient.

2. Description of the Related Art

In the medical field, there have widely been used radiographic image capturing apparatus, which apply radiation to a subject and guide radiation that has passed through the subject to a radiation conversion panel (radiation detector), which captures a radiographic image from such radiation. Known forms of radiation conversion panels include conventional radiation film for recording a radiographic image by way of exposure, and stimulable phosphor panels for storing radiation energy representing a radiographic image in a phosphor, and reproducing the radiographic image as stimulated light by applying stimulating light to the phosphor. Radiation film with the recorded radiographic image is supplied to a developing device to develop the radiographic image, or the stimulable phosphor panel is supplied to a reading device to read the radiographic image as a visible image.

In an operating room or the like, for the purpose of quickly and appropriately treating patients, it is necessary to read a recorded radiographic image immediately from a radiation conversion panel after the radiographic image has been captured. As a radiation detector which meets such a requirement, there have been developed a radiation detector of a direct conversion type (electronic cassette) having a solid-state detector for converting radiation directly into electric signals, and a radiation detector of an indirect conversion type (electronic cassette) having a scintillator for temporarily converting radiation into visible light and a solid-state detector for converting such visible light into electric signals.

In recent years, there have been growing demands for capturing an image of a critically ill patient who cannot easily be moved out of his or her room and also for capturing an image in emergency in an operating room. As a result, there have been increasing needs for apparatus which allow doctors to confirm, quickly with high image quality, images that have been captured in clinical and surgical environments other than X-ray image capturing rooms.

To meet such needs, a mobile radiographic image capturing apparatus has been proposed. As the conventional technology of a mobile radiographic image capturing apparatus, for example, Japanese Laid-Open Patent Publication No. 2009-201561 discloses a mobile medical cart, and Japanese Laid-Open Patent Publication No. 2010-022731 discloses a radiographic image capturing apparatus.

The mobile medical cart in Japanese Laid-Open Patent Publication No. 2009-201561 and the radiographic image capturing apparatus in Japanese Laid-Open Patent Publication No. 2010-022731 comprise a cart unit which is movable by electric power or by hand, and a radiographic apparatus installed in the cart unit. The radiographic apparatus at least has an X-ray source, a cassette housing a stimulable phosphor panel which records radiographic image information of a subject, an image reader for reading radiographic image information from the stimulable phosphor panel in the cassette, and a battery for supplying electric power to devices. In particular, Japanese Laid-Open Patent Publication No. 2009-201561 further discloses an example which uses an electronic cassette housing a solid-state radiation detector, instead of a cassette housing a stimulable phosphor panel.

There has been developed a portable radiographic image capturing apparatus, which can be folded into a compact form in its entirety (see Japanese Laid-Open Patent Publication No. 11-104117, Japanese Laid-Open Patent Publication No. 2007-530979 (PCT), U.S. Pat. No. 4,979,198). In addition, radiation sources comprising field-electron-emission-type electron sources based on carbon nanotube (CNT) technology have also been developed (see Japanese Laid-Open Patent Publication No. 2007-103016, and AIST: Press Release, “Development of Portable X-ray Sources Using Carbon Nanostructures” [online], Mar. 19, 2009, National Institute of Advanced Industrial Science and Technology, Internet <URL:http://www.aist.go.jp/aist_j/press_(—) release/pr2009/pr20090319/pr20090319.html>(hereinafter referred to as “Document 1”). It is expected that small-size, lightweight radiographic image capturing apparatus including radiation sources will become available in the art. Further, a portable size and high energy X-ray source was developed by using LiTaO₃ that is a typical pyroelectric crystal (see “Applying Pyroelectric Crystal to Small High Energy X-Ray Source”, Advances in X-Ray Chemical Analysis, Japan, 41, 2010, pages 195-200 (hereinafter referred to as “Document 2”)).

Wireless electric power transmitting schemes are known from IEDM Plenary Talk, “Arrival of Contactless Power Transmission Sheet Expected to be Embedded in Walls and Floors, developed by the University of Tokyo” [online], Dec. 4, 2006, Internet <URL:http://techon.nikkeibp.co.jp/article/NEWS/20061204/124943/>(hereinafter referred to as “Document 3”), and Nikkei Electronics, “Development of Wireless Power Transmission Technology, a 60-W Lamp Turned on in Experiment,” Dec. 3, 2007, pages 117-128 (hereinafter referred to as “Document 4”). The process disclosed in Document 3 transmits electric power based on electromagnetic induction from a primary coil embedded in a contactless power transmission sheet. The process disclosed in Document 4 is a wireless power transmission technology based on magnetic field resonance between two LC resonators.

SUMMARY OF THE INVENTION

In each of the mobile medical cart disclosed in Japanese Laid-Open Patent Publication No. 2009-201561 and the radiographic image capturing apparatus disclosed in Japanese Laid-Open Patent Publication No. 2010-022731, a dedicated battery is installed. The dedicated battery is a large-sized lead battery, for example, since the battery needs to provide electric power for energizing an X-ray source and an image reader (or electronic cassette), or electric power for moving a medical cart.

In this case, the following problems arise:

(1) It takes time to charge the battery.

(2) It is necessary to provide a special charging facility. For example, a hospital has such a charging facility in a basement.

(3) It is necessary to carry the medical cart to the charging facility.

(4) Since the battery is too heavy to move the medical cart by human power, the medical cart is electrically powered for movement. It is necessary for the medical cart to secure electric power to return to the charging facility, since electric power of the battery is consumed for movement. As a result, further problems arise: (a) The electric power for capturing a radiation image is limited; (b) It is necessary to reduce the number of images to be captured; and (c) It is impossible to attend to unexpected recapturing or additional capturing of radiographic images.

It is conceivable to downsize a radiation source, as shown in Japanese Laid-Open Patent Publication No. 11-104117, Japanese Laid-Open Patent Publication No. 2007-530979 (PCT), U.S. Pat. No. 4,979,198, Japanese Laid-Open Patent Publication No. 2007-103016, and Document 1. This, however, cannot be a fundamental solution to the problems, since a conventional battery still has to be used for securing electric power of such a small radiation source.

An object of the present invention is to provide a radiographic image capturing apparatus which is capable of supplying electric power to a radiation source and a radiation detector even outdoors, reducing consumption of electric power, and minimizing the number batteries used therein, and which can be used easily and efficiently in medical organizations as well as other places such as accident sites, disaster sites, medical checkup sites, home-care service sites, etc.

According to a first aspect of the present invention, there is provided a radiographic image capturing apparatus comprising a mobile cart unit, a plurality of devices used for capturing a radiographic image, and an electric power supply activator enabling supply of electric power between the devices, based on an instruction of permission to supply electric power.

According to the first aspect of the present invention, the devices may at least comprise a radiation source device detachably attached to the cart unit, and including a radiation source for outputting radiation, and a detector device detachably attached to the cart unit, and including a radiation detector for detecting radiation that is transmitted through a subject in a case where the subject is irradiated with the radiation by the radiation source, and converting the detected radiation into radiographic image information, and wherein the electric power supply activator may enable the supply of electric power from the radiation source device to the detector device, or from the detector device to the radiation source device, based on the instruction of permission to supply electric power.

According to the first aspect of the present invention, the radiographic image capturing apparatus may further comprise an electric power manager activatable by the electric power supply activator, based on the instruction of permission to supply electric power, wherein the devices may at least comprises a radiation source device detachably attached to the cart unit, and including a radiation source for outputting radiation, and a detector device detachably attached to the cart unit, and including a radiation detector for detecting radiation that is transmitted through a subject in a case where the subject is irradiated with the radiation by the radiation source, and converting the detected radiation into radiographic image information, and wherein the electric power manager may manage electric power required to capture a given number of radiographic images, and supplies the required electric power flexibly to at least one of the radiation source device and the detector device.

According to the first aspect of the present invention, the devices may at least comprise a radiation source device detachably attached to the cart unit, and including a radiation source for outputting radiation, a detector device detachably attached to the cart unit, and including a radiation detector for detecting radiation that is transmitted through a subject in a case where the subject is irradiated with the radiation by the radiation source, and converting the detected radiation into radiographic image information, and a controller for controlling at least the radiation source device and the detector device, wherein the electric power supply activator may enable supply of electric power from the controller to the radiation source device, or from the controller to the detector device, based on the instruction of permission to supply electric power.

According to the first aspect of the present invention, the devices may at least comprises a radiation source device detachably attached to the cart unit, and including a radiation source for outputting radiation, a detector device detachably attached to the cart unit, and including a stimulable phosphor panel for detecting radiation that is transmitted through a subject in a case where the subject is irradiated with the radiation by the radiation source, and storing the detected radiation as radiographic image information, and an image reading apparatus for reading the radiographic image information that is stored in the stimulable phosphor panel, wherein the electric power supply activator may enable supply of electric power from the radiation source device to the image reading apparatus, or from the image reading apparatus to the radiation source device, based on the instruction of permission to supply electric power.

According to the first aspect of the present invention, the radiographic image capturing apparatus may further comprise an electric power manager activatable by the electric power supply activator, based on the instruction of permission to supply electric power, wherein the devices may at least comprise a radiation source device detachably attached to the cart unit, and including a radiation source for outputting radiation, a detector device detachably attached to the cart unit, and including a stimulable phosphor panel for detecting radiation that is transmitted through a subject in a case where the subject is irradiated with the radiation by the radiation source, and storing the detected radiation as radiographic image information, and an image reading apparatus for reading the radiographic image information that is stored in the stimulable phosphor panel, and wherein the electric power manager may manage electric power required to capture a given number of radiographic images, and supplies the required electric power flexibly to at least one of the radiation source device and the image reading apparatus.

According to the first aspect of the present invention, the devices may at least comprise a radiation source device detachably attached to the cart unit, and including a radiation source for outputting radiation, a detector device detachably attached to the cart unit, and including a stimulable phosphor panel for detecting radiation that is transmitted through a subject in a case where the subject is irradiated with the radiation by the radiation source, and storing the detected radiation as radiographic image information, an image reading apparatus for reading the radiographic image information that is stored in the stimulable phosphor panel and a controller for controlling at least the radiation source device and the image reading apparatus, and wherein the electric power supply activator may enable supply of electric power from the controller to the radiation source device, or from the controller to the image reading apparatus, based on the instruction of permission to supply electric power.

According to the present invention, the radiation source and the radiation detector can be supplied with electric power even if the radiographic image capturing apparatus is used outdoors. The consumption of electric power can be reduced. Batteries that need to be included in the radiographic image capturing apparatus are minimized. Therefore, the radiographic image capturing apparatus is convenient for use in a preset location such as a medical organization, an accident site, a disaster site, a medical checkup site, a home-care service site, etc.

The above and other objects, features, and advantages of the present invention will become more apparent from the following description when taken in conjunction with the accompanying drawings in which preferred embodiments of the present invention are shown by way of illustrative example.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a perspective view of a mobile radiographic image capturing apparatus (first mobile apparatus) according to a first embodiment of the present invention;

FIGS. 2A to 2C are views each showing an attaching/detaching mechanism of a radiation source device to a distal end of an arm;

FIG. 3 is a perspective view of a radiographic apparatus (first radiographic apparatus) used for the first mobile apparatus;

FIG. 4 is a perspective view showing the manner in which the first radiographic apparatus is carried;

FIG. 5 is a horizontal cross-sectional view of the first radiographic apparatus, taken along line V-V of FIG. 3;

FIG. 6 is a cross-sectional view of the first radiographic apparatus, showing a radiation source device separated from a cassette shown in FIG. 3;

FIG. 7 is a cross-sectional view, shown partially in block form, of internal details of the radiation source device shown in FIG. 3;

FIG. 8 is an elevational view, partially in cross section, showing the manner in which the first radiographic apparatus captures a radiographic image;

FIG. 9 is a perspective view showing the manner in which the first radiographic apparatus is readied to capture radiographic images;

FIG. 10 is a perspective view showing the manner in which the first radiographic apparatus captures a radiographic image;

FIG. 11 is a schematic view showing a pixel array of a radiation detector of the first radiographic apparatus;

FIG. 12 is a block diagram of a circuit arrangement of the radiation detector disposed in the cassette;

FIG. 13 is a block diagram of the first radiographic apparatus;

FIG. 14 is a block diagram partially showing a console of the first radiographic apparatus;

FIG. 15 is a perspective view of a modification of the first mobile apparatus (in which printers are installed);

FIG. 16 is a side view, partially broken away, showing the printer installed in a cart unit of the first mobile apparatus;

FIG. 17 is a side view, partially broken away, showing the printer installed in a cassette;

FIG. 18 is a perspective view of a mobile terminal, which displays a radiographic image on a display unit thereof;

FIG. 19 is a block diagram of a battery unit;

FIG. 20 is a block diagram of a battery controller;

FIG. 21 is a block diagram of a power controller according to a first specific example;

FIG. 22 is a block diagram of a power controller (including a power manager) according to a second specific example;

FIG. 23 is a block diagram of a cassette selection activator and a cassette selector;

FIG. 24 is a block diagram of an integrated supply activator and an integrated supply;

FIG. 25 is a block diagram of a power manager;

FIG. 26 is a first flowchart of an operation sequence of the first radiographic apparatus, operated under supply timing conditions, which are free of timing controls;

FIG. 27 is a second flowchart of an operation sequence of the first radiographic apparatus, operated under supply timing conditions, which are free of timing controls;

FIG. 28 is a first flowchart of an operation sequence of the first radiographic apparatus, operated under supply timing conditions for supplying electric power before capturing of radiographic images;

FIG. 29 is a second flowchart of an operation sequence of the first radiographic apparatus, operated under supply timing conditions for supplying electric power before capturing of radiographic images;

FIG. 30 is a third flowchart of an operation sequence of the first radiographic apparatus, operated under supply timing conditions for supplying electric power before capturing of radiographic images;

FIG. 31 is a first flowchart of an operation sequence of the first radiographic apparatus, operated under supply timing conditions for supplying electric power after capturing of radiographic images;

FIG. 32 is a second flowchart of an operation sequence of the first radiographic apparatus, operated under supply timing conditions for supplying electric power after capturing of radiographic images;

FIG. 33 is a block diagram of an electric power collector;

FIG. 34 is a flowchart of an operation sequence of the power collector;

FIG. 35 is a perspective view of a first modification of the first radiographic apparatus;

FIG. 36 is a perspective view of a second modification of the first radiographic apparatus;

FIG. 37 is a perspective view of a third modification of the first radiographic apparatus;

FIG. 38 is a perspective view of a radiographic image capturing apparatus (second mobile apparatus) according to a second embodiment of the present invention;

FIG. 39 is a perspective view of a radiographic apparatus (second radiographic apparatus) used for the second mobile apparatus;

FIG. 40 is a perspective view showing the manner in which the second radiographic apparatus is carried;

FIG. 41 is a horizontal cross-sectional view taken along line XLI-XLI of FIG. 39;

FIG. 42 is a plan view of the second radiographic apparatus, showing a radiation source device separated from a cassette shown in FIG. 39;

FIG. 43 is a cross-sectional view showing the manner in which the second radiographic apparatus captures a radiographic image;

FIG. 44 is a view showing in greater detail a source-to-image distance (SID) that is illustrated in FIG. 43;

FIG. 45 is a perspective view showing the manner in which the second radiographic apparatus is readied to capture radiographic images;

FIG. 46 is a perspective view showing the manner in which the second radiographic apparatus captures a radiographic image;

FIG. 47 is a perspective view of a radiographic image capturing apparatus (third mobile apparatus) according to a third embodiment of the present invention;

FIG. 48 is a block diagram of an image reading apparatus;

FIG. 49 is a schematic view of the image reading apparatus;

FIG. 50 is a cross-sectional view schematically illustrating the structure of three pixel units of a radiation detector according to a modified example of the invention; and

FIG. 51 is a view schematically illustrating the structure of a TFT and a charge storage unit shown in FIG. 50.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

Like or corresponding parts are denoted by like or corresponding reference characters throughout the views.

Embodiments of a radiographic image capturing apparatus according to the present invention will be described in detail below with reference to FIGS. 1 to 51.

A mobile radiographic image capturing apparatus according to a first embodiment of the present invention, which hereinafter will be referred to as a “first mobile apparatus 1000A”, includes a cart unit 1002, at least one portable first radiographic apparatus 10A accommodated in the cart unit 1002, a console 1004 for controlling at least the first radiographic apparatus 10A, and an arm unit 1006 for attaching thereto or detaching therefrom a radiation source device 18 of the first radiographic apparatus 10A.

The console 1004 comprises a notebook-shaped personal computer, including an operating unit 1008 such as a keyboard, and a display unit 1010. The console 1004 is capable of sending signals to and receiving signals from a data center (medical organization etc.) to which an operator belongs, by way of wireless communications via a network such as a public network or the like. Alternatively, the console 1004 may be replaced with a mobile phone or a PDA (Personal Digital Assistant).

As shown in FIG. 2A, an attaching/detaching mechanism 1012 between the radiation source device 18 and the arm unit 1006 may be realized as a mechanism using a female screw 1014 and a male screw 1016. For example, the female screw 1014 is formed on a distal end 1006 a of the arm unit 1006, and the male screw 1016 is formed on a side surface of a cylindrical portion 1018 that is projected on the middle of the radiation source device 18. The radiation source device 18 can be attached to the arm unit 1006 by screwing the male screw 1016 of the radiation source device 18 into the female screw 1014 of the arm unit 1006, and the radiation source device 18 can be detached from the arm unit 1006 by turning the radiation source device 18 in the opposite direction.

As shown in FIG. 2B, the attaching/detaching mechanism 1012 may be realized as a mechanism using an engagement piece 1020. For example, a plurality of openings 1022 are formed on the side surface of the cylindrical portion 1018 that is projected on the middle of the radiation source device 18. In each of the openings 1022, the engagement piece 1020 having, e.g., a triangular cross section is constantly urged by a spring or the like to protrude outward as a protrusion. In this case, a protrusion amount of the engagement piece 1020 gradually increases toward its lower part. The engagement piece 1020 has one side surface that is contiguous to the oblique side of the triangular cross section, and a bottom surface that is contiguous to the bottom side of the triangular cross section. On the other hand, a hole (hollow end) 1024 is formed in a bottom side (distal end surface) of the distal end 1006 a of the arm unit 1006 for inserting the cylindrical portion 1018 of the radiation source device 18. Then, an opening 1026 is formed in the side surface of the distal end 1006 a of the arm unit 1006 for the engagement piece 1020 (protrusion) to enter. If the cylindrical portion 1018 of the radiation source device 18 is inserted into the hole 1024 in the distal end surface of the arm unit 1006, the engagement piece 1020 enters the opening 1026 of the arm unit 1006, and thus the radiation source device 18 is attached to the arm unit 1006. Conversely, if the engagement piece 1020 is pushed inwardly against the spring force or the like, the engagement piece 1020 is released from the engagement with an inner wall of the opening 1026 of the arm unit 1006, and the radiation source device 18 can be detached from the arm unit 1006.

Alternatively, as shown in FIG. 2C, the attaching/detaching mechanism 1012 may be realized using a magnet, provided that the magnet does not affect the generation of radiation. For example, a metal piece 1028 is applied to a top surface of the cylindrical portion 1018 that is projected on the middle of the radiation source device 18, while a magnet sheet 1030 is applied to a distal end surface 1006 b of the arm unit 1006. If the metal piece 1028 on the top surface of the cylindrical portion 1018 of the radiation source device 18 is brought into contact with the magnet sheet 1030 on the distal end surface 1006 b of the arm unit 1006, the radiation source device 18 is attached to the arm unit 1006 by magnetic attraction. Conversely, the radiation source device 18 can be detached easily from the arm unit 1006 by separating them from each other against the magnetic attraction.

As shown in FIG. 1, the cart unit 1002 has a plurality of wheels 1032, and is movable by human power using a handle 1034. Alternatively, the cart unit 1002 can be electrically powered for movement. The cart unit 1002 also has a plurality of slots 1036 for accommodating respective pieces of the first radiographic apparatus 10A. Each piece of the first radiographic apparatus 10A may have the same size or a different size.

As shown in FIG. 3, the first radiographic apparatus 10A includes a cassette 12 having a substantially rectangular outer contour shaped as a housing, and which is made of a material permeable to radiation 46 (see FIG. 8), and the cylindrical radiation source device 18 held in the cassette 12 by a pair of holders 16 a, 16 b, which project outwardly from opposite ends of one side 14 a of the cassette 12. A radiation source device 18 of a first radiographic apparatus 10A can be replaced with a radiation source device 18 of another first radiographic apparatus 10A. Also, a cassette 12 of a first radiographic apparatus 10A can be replaced with a cassette 12 of another first radiographic apparatus 10A.

The cassette 12 has crisscross guide lines 22 disposed on a surface (irradiated surface) 20 thereof, which serve as a reference for an image capturing area and an image capturing position. The cassette 12 also has a grip 24 on another side 14 b thereof remote from the one side 14 a. The cassette 12 has two other sides 14 c, 14 d extending perpendicular to and between the sides 14 a, 14 b, which are opposite to each other. On the side 14 c, there are disposed a USB (Universal Serial Bus) terminal 28 as an interface means for sending information to and receiving information from an external device, a card slot 32 for insertion of a memory card 30 therein, and an unlocking button 34 to be described later. The side 14 c also supports thereon a mobile terminal 42, which is detachable from the cassette 12. The mobile terminal 42 includes a display unit 36 and an operating unit 40 having a number of control buttons operable by a doctor or radiological technician (hereinafter referred to as an “operator”) 38 who handles the first radiographic apparatus 10A. The radiation source device 18 has an exposure switch 48, which can be operated by the operator 38 in order to cause a radiation source 44 (see FIG. 8), which shall be descried later, to start emitting radiation 46.

FIGS. 3 and 4 show the first radiographic apparatus 10A, which is taken out from the slots 1036 of the cart unit 1002 by the operator 38. In this state, the radiation source device 18 and the cassette 12 are integrally joined to each other.

As shown in FIG. 1, the operator 38 moves the cart unit 1002 toward a subject 50 whose radiographic images are to be captured (including a victim at the accident site or the disaster site, or an examinee at the medical checkup site, or a person receiving home-care services at home). Then, the operator 38 takes out the first radiographic apparatus 10A from the cart unit 1002, and separates the cassette 12 from the radiation source device 18. Thereafter, the radiation source device 18 is attached to the distal end 1006 a of the arm unit 1006. If recumbent image capturing is to be carried out, for example, the cassette 12 is disposed between the subject 50 and a bed 1040 or a sheet (blanket etc.). Then, the operator 38 turns on an electric power supply switch (ON operation). The ON operation of the electric power supply switch includes the clicking of the left button of a mouse on an icon representing an electric power supply switch shown on the display unit 1010 of the console 1004. Alternatively, the ON operation may be performed using an operation switch on the cart unit 1002 that is dedicated for electric power supply operation. Accordingly, at an above-mentioned site or the like, radiographic images of the subject 50 can be captured using the first radiographic apparatus 10A.

If the radiation source device 18 and the cassette 12 are joined to each other integrally, they are secured together by a joining mechanism 82 (see FIG. 5), to be described later, so that the first radiographic apparatus 10A can be carried by the operator 38.

Next, the portable first radiographic apparatus 10A will be described in detail below with reference to FIGS. 5 to 19.

As shown in FIG. 5, the sides 14 a, 14 b, 14 c, 14 d of the cassette 12 are constituted by respective side walls 52 a, 52 b, 52 c, 52 d. The USB terminal 28, the card slot 32, and the unlocking button 34 are provided on the side wall 52 c. The side wall 52 c has a recess 54, which is defined between the card slot 32 and the unlocking button 34. The mobile terminal 42 (see FIG. 3) can be placed in the recess 54.

If the unlocking button 34 is pressed by the operator 38 (see FIG. 4), the unlocking button 34 is displaced along the side wall 52 a toward the side wall 52 d. A slide 56 projects along the side wall 52 a from a surface of the unlocking button 34 that faces the side wall 52 d, and a spring 60 acts between the slide 56 and a tooth 58 that projects inwardly from the side wall 52 a. The spring 60 normally biases the unlocking button 34 to move in a direction from the tooth 58 toward the side wall 52 c. The side wall 52 a has a through hole 62 defined in a portion thereof against which the slide 56 slides, the through hole 62 extending from an inner surface of the side wall 52 a to an outer surface thereof. The slide 56 has a hook 64, which extends through the through hole 62.

As shown in FIGS. 5 and 6, the radiation source device 18 has a through hole 66 defined therein at a location aligned with the through hole 62 of the cassette 12 in a case where the radiation source device 18 is held in the cassette 12 by the holders 16 a, 16 b. The through hole 66 is of substantially the same size as the through hole 62. In a case where the hook 64 is displaced toward the side wall 52 c under the bias of the spring 60, the hook 64 engages with an edge of the through hole 66 and locks the radiation source device 18 in place, thereby integrally joining the radiation source device 18 to the cassette 12 (see FIG. 5).

The radiation source device 18 has an electrically conductive connection terminal (first radiation source connection terminal) 68 a mounted on an end thereof that faces the holder 16 a, and also has an electrically conductive connection terminal (second radiation source connection terminal) 68 b mounted on another end thereof that faces the holder 16 b. The first connection terminal 68 a is convex in shape toward the holder 16 a, whereas the second connection terminal 68 b is concave in shape toward the holder 16 b. The radiation source device 18 has a first energy input/output unit 300, or a second energy input/output unit 302 (see FIG. 19) for inputting and outputting electric power through a contact (wired or the like) link or a contactless (wireless or the like) link, for example. The first radiation source connection terminal 68 a and the second radiation source connection terminal 68 b, for example, constitute the first energy input/output unit 300 or the second energy input/output unit 302, respectively, and may be electrically connected through a wireless link. The first energy input/output unit 300 or the second energy input/output unit 302 is mounted on a side wall of the radiation source device 18 (see FIG. 3).

The holder 16 a of the cassette 12 has an electrically conductive connection terminal (first cassette connection terminal) 70 a on a surface thereof that faces the radiation source device 18. The holder 16 b of the cassette 12 has an electrically conductive connection terminal (second cassette connection terminal) 70 b on a surface thereof that faces the radiation source device 18. The first connection terminal 70 a is concave, complementary in shape to the first convex connection terminal 68 a, whereas the second connection terminal 70 b is convex, complementary in shape to the second concave connection terminal 68 b. The cassette 12 has a first energy input/output unit 300 or a second energy input/output unit 302 (see FIG. 19) for inputting and outputting electric power through a contact (wired or the like) link or a contactless (wireless or the like) link, for example. The first cassette connection terminal 70 a and the second cassette connection terminal 70 b, for example, constitute the first energy input/output unit 300 or the second energy input/output unit 302, and may be electrically connected through a wireless link. The first energy input/output unit 300 or the second energy input/output unit 302 is mounted on the side 14 c of the cassette 12.

As shown in FIG. 5, in a case where the hook 64 engages the edge of the through hole 66 under the resiliency of the spring 60 in order to keep the radiation source device 18 and the cassette 12 joined integrally with each other, the first convex connection terminal 68 a and the first concave connection terminal 70 a engage with each other, and the second concave connection terminal 68 b and the second convex connection terminal 70 b engage with each other, respectively. Therefore, the radiation source device 18 and the cassette 12 are securely and integrally joined with each other. Consequently, the connection terminals 68 a, 68 b, 70 a, 70 b function as members for assisting the hook 64 and the through hole 66 in maintaining the radiation source device 18 and the cassette 12 in an integrally joined condition.

As shown in FIG. 6, in a case where the operator 38 presses the unlocking button 34 to move the unlocking button 34 toward the side wall 52 d against the resiliency of the spring 60, the hook 64 and the slide 56 are displaced toward the side wall 52 d, so as to bring the hook 64 out of engagement with the edge of the through hole 66. While the hook 64 is kept out of engagement with the edge of the through hole 66, i.e., while the operator 38 presses the unlocking button 34, the operator 38 can remove or separate the radiation source device 18 from the cassette 12, whereby the radiation source device 18 and the cassette 12 are released from each other. The released radiation source device 18 is attached to the distal end of the arm unit 1006 shown in FIG. 1.

The cassette 12 houses therein a tape measure 72 comprising a ribbon 76 marked with graduations 74, which is coiled into a roll by a spring, not shown, in the tape measure 72. The tape measure 72 is combined with a rotary encoder 78 on one side thereof, for detecting the length by which the ribbon 76 is reeled out from the tape measure 72. The ribbon 76, which is reeled out from the tape measure 72, extends through a hole 80 that is defined in the side wall 52 a at a location facing the tape measure 72, and a distal end of the ribbon 76 is fixed to the radiation source device 18 near the second connection terminal 68 b.

In a case where the radiation source device 18 and the cassette 12 are joined integrally with each other as shown in FIG. 5, most of the ribbon 76 is coiled into a roll inside the tape measure 72 under the resiliency of the spring. On the other hand, in a case where the radiation source device 18 and the cassette 12 are not joined integrally with each other, as shown in FIGS. 6 through 10, the ribbon 76 can be pulled out of the tape measure 72 through the hole 80 by separating the radiation source device 18 away from the cassette 12 against the resiliency of the spring.

The unlocking button 34, the slide 56, the spring 60, the hook 64, the connection terminals 68 a, 68 b, 70 a, 70 b, and the tape measure 72 jointly make up a joining mechanism 82 for integrally joining the radiation source device 18 and the cassette 12 with each other in a case where the first radiographic apparatus 10A is carried, and also for enabling the radiation source device 18 and the cassette 12 to be separated from each other in a case where the first radiographic apparatus 10A is utilized to capture radiographic images.

The tape measure 72 comprises the ribbon 76, which is marked with graduations 74 in the illustrated embodiment. However, as a functional equivalent to the ribbon 76, the tape measure 72 may comprise a string marked with graduations 74.

As shown in FIGS. 5 and 8, the cassette 12 also houses therein a grid 84 for removing scattered rays of radiation 46 from the subject 50 in a case where the radiation source 44 applies radiation 46 with respect to the subject 50, a radiation detector 86 for detecting radiation 46 that has passed through the subject 50, and a lead plate 88 for absorbing back scattered rays of radiation 46, which are successively arranged in this order from the irradiated surface 20 of the cassette 12. The irradiated surface 20 of the cassette 12 may also be constructed as the grid 84.

The radiation detector 86 may comprise a radiation detector (including a front surface reading type and a rear surface reading type) of an indirect conversion type, including a scintillator for converting radiation 46 that has passed through the subject 50 into visible light, and solid-state detectors (hereinafter also referred to as pixels) made of amorphous silicon (a-Si) or the like for converting the visible light into electric signals. A radiation detector of ISS (Irradiation Side Sampling) type as a front surface reading type, comprises solid-state detectors and a scintillator that are successively provided along an irradiation direction of the radiation 46. A radiation detector of PSS (Penetration Side Sampling) type as a rear surface reading type, comprises a scintillator and solid-state detectors that are successively provided along the irradiation direction of the radiation 46. As well as the above-described indirect conversion type, the radiation detector 86 may comprise a radiation detector of a direct conversion type, comprising solid-state detectors made of amorphous selenium (a-Se) or the like for converting a dose of radiation 46 directly into electric signals.

As shown in FIG. 5, the cassette 12 also houses therein a battery unit 304 as a power supply for the cassette 12, a battery controller 306 for limiting and controlling supply of electric power to the battery unit 304, a cassette controller 92 for controlling the radiation detector 86 (see FIG. 8) with electric power supplied from the battery unit 304, and a transceiver 94 for sending and receiving signals including information concerning radiation 46 that is detected by the radiation detector 86, to and from an external circuit. A plate of lead or the like should preferably be placed over the side surfaces of the cassette controller 92 and the transceiver 94 under the irradiated surface 20 in order to protect the cassette controller 92 and the transceiver 94 against damage, which would otherwise be caused if the cassette controller 92 and the transceiver 94 were irradiated with radiation 46.

The battery unit 304 supplies electric power to the rotary encoder 78, the radiation detector 86, the cassette controller 92, and the transceiver 94 in the cassette 12. The battery unit 304 can also charge the mobile terminal 42 in a case where the mobile terminal 42 is placed in the recess 54. As shown in FIG. 19, the battery unit 304 includes, in addition to the first energy input/output unit 300 and the second energy input/output unit 302, a battery (electric power storage unit) 308, a first energy converter 310, and a second energy converter 312. The battery unit 304 can be supplied with (i.e., charged by) electric power from an external circuit, or can supply electric power to an external circuit, over a wired or wireless link via the first energy input/output unit 300 and/or the second energy input/output unit 302. That is, contact or contactless electric power supply is available. A first switcher 314 a is connected between the first energy input/output unit 300 and the first energy converter 310. A second switcher 314 b is connected between the second energy input/output unit 302 and the second energy converter 312. Third through fifth switchers 314 c through 314 e are connected between the battery 308 and the first energy input/output unit 300 and the second energy input/output unit 302.

The first energy converter 310 comprises a first input converter 316 and a first output converter 318. The second energy converter 312 comprises a second input converter 320 and a second output converter 322. For inputting electric power via the first energy input/output unit 300, the first switcher 314 a electrically connects the first energy input/output unit 300 and the first input converter 316 to each other, while the third switcher 314 c and the fifth switcher 314 e electrically connect the first input converter 316 and the battery 308 to each other. Conversely, for outputting electric power via the first energy input/output unit 300, the first switcher 314 a electrically connects the first energy input/output unit 300 and the first output converter 318 to each other, while the third switcher 314 c and the fifth switcher 314 e electrically connect the first output converter 318 and the battery 308 to each other. Similarly, for inputting electric power via the second energy input/output unit 302, the second switcher 314 b electrically connects the second energy input/output unit 302 and the second input converter 320 to each other, while the fourth switcher 314 d and the fifth switcher 314 e electrically connect the second input converter 320 and the battery 308 to each other. Conversely, for outputting electric power via the second energy input/output unit 302, the second switcher 314 b electrically connects the second energy input/output unit 302 and the second output converter 322 to each other, while the fourth switcher 314 d and the fifth switcher 314 e electrically connect the second output converter 322 and the battery 308 to each other. The first through fifth switchers 314 a through 314 e are controlled by an electric power supply controller 374, to be described later, in order to make such connections.

The first energy input/output unit 300, the second energy input/output unit 302, the first energy converter 310, and the second energy converter 312 have different structures depending on the type of energy to be supplied (supplied energy).

For example, if electric energy is supplied through wired connections such as cables, connection terminals, etc., then the first energy input/output unit 300 comprises a connector, which is connected to cables and connection terminals. The first input converter 316 comprises a voltage converter or the like for converting a voltage applied from the first energy input/output unit 300 through the first switcher 314 a into a voltage that is optimum for charging the battery 308. The first output converter 318 comprises a voltage converter or the like for converting a voltage output from the battery 308 through the fifth switcher 314 e and the third switcher 314 c into a voltage that is optimum for power transmission. The second energy input/output unit 302 and the second energy converter 312 also are of a similar construction.

If electric energy is supplied by way of electromagnetic induction through a coil (primary coil or secondary coil) embedded in a contactless power transmission sheet, for example as disclosed in Document 3, then the first energy input/output unit 300 comprises a secondary coil or a primary coil, whereas the first input converter 316 comprises a voltage converter or the like for converting a voltage generated by the first energy input/output unit 300, which functions as a secondary coil, into a voltage that is optimum for charging the battery 308. Further, the first output converter 318 comprises a voltage-to-current converter for converting a voltage output from the battery 308 through the fifth switcher 314 e and the third switcher 314 c into a current that flows to the first energy input/output unit 300, which functions as a primary coil. The second energy input/output unit 302 and the second energy converter 312 also are of a similar construction.

If electric energy is supplied by way of wireless power transmission technology based on magnetic resonance as disclosed in Document 4, then the first energy input/output unit 300 comprises a second LC resonator or a first LC resonator, which is combined with a first LC resonator or a second LC resonator of an electric power transmitter, whereas the first input converter 316 comprises a coil, i.e., a secondary coil combined with a primary coil as the coil of the second LC resonator, for converting electromagnetic energy generated by the first energy input/output unit 300, which functions as the second LC resonator. Further, the first output converter 318 comprises a coil, i.e., a primary coil combined with a secondary coil as the coil of the first LC resonator, for outputting a voltage output from the battery 308 through the fifth switcher 314 e and the third switcher 314 c as electromagnetic energy from the first energy input/output unit 300, which functions as the first LC resonator. The second energy input/output unit 302 and the second energy converter 312 also are of a similar construction.

The supplied energy may be optical energy or thermal energy. If the supplied energy is optical energy, then an energy receiver is provided, which comprises a photodetector for detecting optical energy, and an energy converter is provided, which comprises a photoelectric transducer (photoelectric converter) for converting the detected optical energy into electric power. If the supplied energy is thermal energy, then an energy receiver is provided, which comprises a thermal sensor for detecting thermal energy, and an energy converter is provided, which comprises a thermoelectric transducer, i.e., a thermoelectric transducer based on the Seebeck Effect, for converting the detected thermal energy into electric power.

The battery 308 may comprise a secondary battery, such as a nickel hydrogen battery, a nickel cadmium battery, a lithium battery, or the like, or a capacitor, such as a catalytic capacitor, an electric double-layer capacitor, a lithium ion capacitor, or the like. The battery 308 may be detachably mounted on the cassette 12. The battery 308 may comprise a small-size built-in capacitor, which is capable of storing an amount of electric power required to capture at least one radiographic image.

Since the transceiver 94 is capable of sending signals to and receiving signals from an external circuit, the transceiver 94 can send signals to and receive signals from a transceiver 98 (see FIG. 13) of the mobile terminal 42, which is removed from the recess 54, and also can send signals to and receive signals from a transceiver 100 of the radiation source device 18, which is separated from the cassette 12. Even if the cassette 12 and the radiation source device 18 are integrally coupled to each other and/or if the mobile terminal 42 is placed in the recess 54, the transceiver 94 can send signals to and receive signals from the transceivers 98, 100.

As shown in FIG. 7, the radiation source device 18 houses therein the radiation source 44, a battery unit 304, a battery controller 306 for controlling the battery unit 304, a transceiver 100, a radiation source controller 102 for controlling the radiation source 44, and a laser pointer 104. The first energy input/output unit 300 and the second energy input/output unit 302, which are identical to those provided on the cassette 12, are mounted on a side wall of the casing of the radiation source device 18.

The radiation source 44 comprises a field-electron-emission-type radiation source, which is similar to the field-electron-emission-type radiation source disclosed in Japanese Laid-Open Patent Publication No. 2007-103016.

The radiation source 44 includes a disk-shaped rotary anode 110 mounted on a rotational shaft 108, which can be rotated about its axis by a rotating mechanism 106, an annular target layer 112 disposed on the surface of the rotary anode 110 and made up principally from a metallic element such as Mo or the like, a cathode 114 disposed in confronting relation to the rotary anode 110, and a field-electron-emission-type electron source 116 disposed on the cathode 114 in confronting relation to the target layer 112.

In a case where the operator 38 operates the exposure switch 48, the radiation source controller 102 controls the radiation source 44 to output radiation 46. More specifically, in a case where the radiation source 44 is controlled by the radiation source controller 102, the rotating mechanism 106 rotates the rotational shaft 108 so as to rotate the rotary anode 110. The battery unit 304 supplies electric power to a power supply 118, which applies a negative voltage to the field-electron-emission-type electron source 116. The battery unit 304 also supplies electric power to a power supply 120, which applies a voltage between the rotary anode 110 and the cathode 114. More specifically, a positive voltage is applied to the rotary anode 110, whereas a negative voltage is applied to the cathode 114. The field-electron-emission-type electron source 116 emits electrons, which are accelerated and bombard the target layer 112 due to the voltage applied between the rotary anode 110 and the cathode 114. The electrons are focused onto a focus point 122 on the surface of the target layer 112, and the bombarded surface of the target layer 112 emits radiation 46 from the focus point 122 at an intensity level depending on the applied electrons. As the radiation source 44, a portable size and high energy X-ray source that is disclosed in Document 2 and uses a crystal of tourmaline, LiNbO₃, LiTaO₃, ZnO, and the like, may be employed. In this case, for example, about 100 kV voltage can be generated by using LiNbO₃, whose axial length is 1 cm.

For irradiating the subject 50 with radiation 46 in order to capture radiographic images of the subject 50, it is necessary first to perform a preparatory procedure, thus readying the first radiographic apparatus 10A for capturing radiographic images. The preparatory procedure includes a process for presetting a source-to-image distance (SID), which represents the distance (imaging distance) between the focus point 122 of the radiation source 44 and a position 124 (see FIG. 8) on the radiation detector 86 located directly beneath the focus point 122, and a process for bringing the center of a range within which the irradiated surface 20 is irradiated with radiation 46 into alignment with a central position 126, i.e., a point of intersection, of the aforementioned crisscross guide lines 22.

The preparatory procedure is carried out as follows. As shown in FIGS. 8 and 9, while the radiation source device 18 is separated from the cassette 12, the operator 38 pulls the ribbon 76 from the tape measure 72 until the length of the ribbon 76, which is reeled out from the tape measure 72, is equal to a reeled-out length 11 that depends on the SID. The laser pointer 104 is controlled by the radiation source controller 102 to apply and focus a laser beam 128 on the irradiated surface 20, in order to display a crisscross mark 130 on the irradiated surface 20, which represents the center of a range within which the irradiated surface 20 is irradiated with radiation 46.

The SID, the reeled-out length 11 that depends on the SID, and a distance 12 between the position 124 or the central position 126 and the side 14 a, which has the hole 80 through which the ribbon 76 is pulled out, are related to each other according to the equation SID≈(11²−12²)^(1/2). The distance 12 is constant.

After the ribbon 76 has been pulled out from the tape measure 72 by the reeled-out length 11, the operator 38 positionally adjusts the radiation source device 18 so as to bring the mark 130 displayed on the irradiated surface 20 into alignment with the central position 126. Thereafter, the operator 38 turns on the exposure switch 48 to cause the radiation source 44 to apply radiation 46 to the subject 50 on the irradiated surface 20, thereby capturing radiographic images of the subject 50, as shown in FIG. 10. In FIG. 10, an example is shown in which a radiographic image of a hand of the subject 50 is captured.

As shown in FIG. 11, the radiation detector 86 comprises a number of pixels 132 arrayed on a substrate, not shown, a number of gate lines 134 for supplying control signals to the pixels 132, and a number of signal lines 136 for reading electric signals output from the pixels 132.

A circuit arrangement of the radiation detector 86, which is of an indirect conversion type, for example, that is housed in the cassette 12, will be described in detail below with reference to FIG. 12.

As shown in FIG. 12, the radiation detector 86 comprises an array of thin-film transistors (TFTs) 140 arranged in rows and columns, and a photoelectric conversion layer 138 including the pixels 132, and made of a material such as amorphous silicon (a-Si) or the like for converting visible light into analog electric signals. The photoelectric conversion layer 138 is disposed on the array of TFTs 140. In a case where radiation 46 is applied to the radiation detector 86, the pixels 132 generate electric charges by converting visible light into analog electric signals. Then, in a case where the TFTs 140 are turned on one row at a time, electric charges are read from the pixels 132 as image signals.

The TFTs 140 are connected respectively to the pixels 132. The gate lines 134, which extend parallel to the rows, and the signal lines 136, which extend parallel to the columns, are connected to the TFTs 140. The gate lines 134 are connected to a line scanning driver 142, and the signal lines 136 are connected to a multiplexer 144. The gate lines 134 are supplied with control signals Von, Voff from the line scanning driver 142 for turning on and off the TFTs 140 along the rows. The line scanning driver 142 comprises a plurality of switches SW1 for switching between the gate lines 134, and an address decoder 146 for outputting a selection signal for selecting one of the switches SW1 at a time. The cassette controller 92 supplies an address signal to the address decoder 146.

The signal lines 136 are supplied with electric charges stored by the pixels 132 through the TFTs 140 arranged in the columns. The electric charges supplied to the signal lines 136 are amplified by amplifiers 148, which are connected respectively to the signal lines 136. The amplifiers 148 are connected through respective sample and hold circuits 150 to the multiplexer 144. The multiplexer 144 comprises a plurality of switches SW2 for successively switching between the signal lines 136, and an address decoder 152 for outputting selection signals for selecting one of the switches SW2 at a time. The address decoder 152 is supplied with an address signal from the cassette controller 92. The multiplexer 144 has an output terminal connected to an A/D converter 154. Radiographic image signals, which are generated by the multiplexer 144 based on electric charges from the sample and hold circuits 150, are converted by the A/D converter 154 into digital image signals representing radiographic image information, which is supplied to the cassette controller 92.

The TFTs 140, which function as switching devices, may be combined with another image capturing device, such as a CMOS (Complementary Metal-Oxide Semiconductor) image sensor or the like. Alternatively, the TFTs 140 may be replaced with a CCD (Charge-Coupled Device) image sensor for shifting and transferring electric charges with shift pulses that correspond to gate signals in the TFTs.

FIG. 13 shows in block form the first radiographic apparatus 10A. Components of the first radiographic apparatus 10A, which have not been described above with reference to FIGS. 3 through 12, will mainly be described below with reference to FIG. 13.

The cassette controller 92 comprises an address signal generator 162, an image memory 164, and an SID determining unit (imaging distance determining unit) 168.

The address signal generator 162 supplies address signals to the address decoder 146 of the line scanning driver 142, as well as to the address decoder 152 of the multiplexer 144. The image memory 164 stores the radiographic image information detected by the radiation detector 86.

The SID determining unit 168 calculates the imaging distance between the focus point 122 and the position 124, in a case where the radiation source device 18 is tentatively placed over the irradiated surface 20 according to the present reeled-out length 11 of the ribbon 76, based on the reeled-out length 11 of the ribbon 76, which is input from the rotary encoder 78, and the stored distance 12.

If the calculated imaging distance agrees with the SID, the SID determining unit 168 controls the display unit 36 through the transceivers 94, 98, so as to display information representing the present reeled-out length of the ribbon 76 as the reeled-out length 11 that depends on the SID, and also to display information representing that the imaging distance agrees with the SID. The cassette 12 may include a mechanism for preventing (locking) the ribbon 76 from being reeled out further, in a case where the reeled-out length 11 and the imaging distance have been determined to agree with the SID. If the calculated imaging distance does not agree with the SID, then the SID determining unit 168 controls the display unit 36 through the transceivers 94, 98 in order to display information representing the difference between the present reeled-out length and the reeled-out length 11, and also to display information representing that the imaging distance does not agree with the SID.

The SID determining unit 168, the rotary encoder 78, and the tape measure 72 jointly make up an imaging distance setting means 169.

The cassette controller 92 can transmit cassette ID information of the cassette 12 and radiographic image information, which are stored in the image memory 164, via the transceiver 94 to the mobile terminal 42 by way of wireless communications.

A printer 170 a may be installed in the radiation source device 18 for printing the data from the radiation source controller 102. Also, a printer 170 b may be installed in the cassette 12 for printing the data from the cassette controller 92. Usually, for a printer of medical use, there is a thermal printer for a transparent manuscript (first printer) or an ink-jet printer for a reflective manuscript (second printer). If the second printer is used as the printer 170 a and the printer 170 b, the radiation source device 18 and the cassette 12 using the same can be downsized. Both the first and second printers consume large electric power. For the first printer, especially, a thermal head printer will be used if it should be downsized (see, e.g., Japanese Laid-Open Patent Publication No. 10-051635), but electric power consumption may be extremely large. Therefore, if the electric power supply is controlled such that the remaining levels of electric power stored in the batteries 308 in the devices are utilized flexibly, which will be described later, then a printer having large electric power consumption may be used as the printer 170 a or the printer 170 b.

The first mobile apparatus 1000A is carried (moved) to an accident or disaster site, as well as a patient room in the hospital or a home of a person (patient) receiving home-care services. In the accident site and the like, the first mobile apparatus 1000A may be contaminated by dust, mud, or dirty water. In the cassette 12 and the radiation source device 18 of the first radiographic apparatus 10A, at least a portion surrounding an electric system thereof is often sealed. Therefore, contactless electric power supply through wireless connections or the like is desirable for an electric power supply method, compared to contact electric power supply by wired connections or the like.

The console 1004 has a power supply switch, speakers, a microphone, and other accessories, similar to those of ordinary notebook-shaped personal computers. The console 1004 incorporates therein a transceiver 288 (see FIG. 14) for sending information to and receiving information from an external device such as a network, the radiation source device 18, the cassette 12, or the like. The console 1004 also includes, on a side wall thereof, a first energy input/output unit 300, and a second energy input/output unit 302. In this case, the first energy input/output unit 300 of the console 1004 is connected by a cable to the first energy input/output unit 300 of the radiation source device 18 of the first radiographic apparatus 10A, while the second energy input/output unit 302 of the console 1004 is connected by a cable to the first energy input/output unit 300 of the cassette 12 of the first radiographic apparatus 10A. However, the first energy input/output unit 300 and the second energy input/output unit 302 may be connected wirelessly (referred to as a “wireless connection”, or a connection in a wireless fashion, etc.) in an area, where the first radiographic apparatus 10A can utilize wireless electric power supply.

The console 1004 includes therein a battery unit 304 and a battery controller 306, which are identical to those of the cassette 12 and the radiation source device 18.

A printer 170 c may be installed in the first mobile apparatus 1000A for printing the data from the console 1004. For the printer 170 c, the aforementioned first or second printer may be used. In this case, also, as described later, if the electric power supply is controlled such that the remaining levels of electric power stored in the batteries 308 in the devices are utilized flexibly, which will be described later, then a printer having large electric power consumption may be used.

For example, the printer 170 c installed in the cart unit 1002 and the printer 170 b installed in the cassette 12 will be described below with reference to FIGS. 15 through 17.

First, the printer 170 c installed in the cart unit 1002 is a device, in which using a recording material that does not require wet development processing, the recording material is exposed by means of scanning exposure with light beams composed of laser light to form a latent image, then heat developed to obtain a visible image, and followed by cooling to the ordinary temperature. As shown in FIG. 15, the printer 170 c has a recording material loading section 176 on a side surface of the cart unit 1002, for loading a recording material cartridge 174 in which a recording material 172 (see FIG. 16) is housed. The recording material 172 wound in a rolled shape is accommodated in the recording material cartridge 174.

As shown in FIG. 16, the printer 170 c is basically provided with a recording material feed section 178, an image exposure section 180 as recording means, a heat development section 182, and a cooling section 184 in the order of the feed direction of the recording material 172. Also, the printer 170 c is provided with feed means for feeding the recording material 172, and a printer control section 186 for driving and controlling the respective sections. The feed means are provided at important points among the respective sections.

The recording material feed section 178 is provided with the recording material loading section 176 (see FIG. 15), a feed roller pair 188, and a cutter 190. The recording material cartridge 174 is loaded detachably into the recording material loading section 176 shown in FIG. 15. For the recording material cartridge 174, plural kinds of cartridges are prepared depending upon the size of the recording material 172 to be accommodated (for example, B4 (257×364 mm), HANSETSU (14×17 inch), MUTSUGIRI (8×10 inch), and the like). As shown in FIG. 15, the recording material cartridge 174 has a size identification symbol on a side thereof for visually confirming the size of the recording material 172 loaded therein easily, such as “B4” for the recording material 172 of B4 size, “H” for the recording material 172 of the HANSETSU size, “M” for the recording material 172 of the MUTSUGIRI size, and the like. In loading the recording material cartridge 174 into the recording material loading section 176 corresponding to the size, size information is input into the printer control section 186 manually by an operator 38 (e.g., using an operating unit 1008), or by detecting a bar code 192 attached to the outer surface of the cartridge 174 by a recognition sensor (not shown) within the recording material loading section 176.

In the recording material cartridge 174, a case thereof is formed so as to have sealing properties, the inside thereof forms an accommodation space of the rolled recording material 172, and this accommodation space is opened to an outlet 174 a. That is, the tip end of the recording material 172 on the sending-out side is drawn out from the outlet 174 a.

The tip end portion drawn out from the outlet 174 a of the recording material cartridge 174 is sandwiched by a feed roller pair 188 and is sent out from the recording material cartridge 174 by rotation of the feed roller pair 188. The cutter 190 is aligned in the downstream side of the recording material feed direction of the feed roller pair 188 and cuts the recording material 172 sent out by the feed roller pair 188 into a prescribed length. Cutting of the recording material 172 is carried out by detecting the sending-out length of the recording material 172 from the rotation amount of the feed roller pair 188 or by a non-illustrated sensor and controlling the actuation of the cutter 190 by the printer control section 186 based on the detected value.

The image exposure section 180 scans and exposes the recording material 172 having been fed from the recording material feed section 178 with light beams L in the major scanning direction (substantially perpendicular to the feed direction of the recording material 172) and feeds the recording material 172 in the sub-scanning direction (the feed direction of the recording material 172), thereby recording a desired image (e.g., radiographic image information) on the recording material 172 to form a latent image.

The heat development section 182 heats a recording material to be heated, to which heat treatment is applied. With respect to the construction of the heat development section 182, one or more plate heaters 194 are lined in the feed direction of the recording material 172, as heating bodies which will reach a temperature necessary for processing the recording material 172.

In the heat development section 182 including the heaters 194, the recording material 172 is slipped and relatively moved while being brought into contact with the upper surface of each plate heater 194. In this case, as feed means of the recording material 172, a feed roller 196 and a plurality of press rollers 198 which also function to achieve heat conduction into the recording material 172 from each plate heater 194, are aligned. As the press rollers 198, a metal roller, a resin roller, a rubber roller, and the like can be utilized. Non-illustrated discharge rollers for feeding the recording material 172 are aligned at the terminal of the feed path within the heat development section 182.

The recording material 172 having been fed out from the heat development section 182 is cooled in the cooling section 184 while being fed by the cooling roller pairs 200. The recording material 172 discharged from the cooling section 184 is guided into a guide plate 202 provided on the way of the feed path and further discharged into a discharge tray 206 from a discharge roller pair 204. The operator 38 can visually confirm the image (e.g., radiographic image information) recorded on the recording material 172 having a prescribed length and discharged from the discharge tray 206. Further, since the printer 170 c is the aforementioned first printer, a printed image has such a high image quality that interpretation of radiogram can be performed.

Incidentally, as shown in FIGS. 15 and 17, the printer 170 b is housed in a installation space 208 in a housing 14 of a cassette 12, which is positioned close to a side 14 b having a grip 24 thereon. An opening 210 is provided in the housing 14, for example, at a position close to the side 14 b on the irradiated surface 20, for sending out the tip end of the recording material 172 from the housing 14. The recording material 172 is replaceably received in the installation space 208. Further, the grip 24 (grip unit 25) may be detachable from the cassette 12. In this case, the printer 170 b may also be detachable from the cassette 12 together with the grip unit 25. For example, the printer 170 b may be detachably attached to the cassette 12 using hooks 211 and the like. FIG. 17 shows that the hooks 211 formed on the printer 170 b engage the cassette 12. For detaching the printer 170 b, the portions of the printer 170 b that are close to the hooks 211 are pushed along directions indicated by dashed arrows 212. Then, the engagement of the hooks 211 with the cassette 12 can be released.

The printer 170 b has a supply roller pair 213 for sending out the tip end of the recording material 172, a print head 214 for printing a desired image (e.g., radiographic image information) on the recording material 172, a feed roller pair 216 for feeding to the opening 210 the recording material 172 on which an image or the like is printed, and a cutter 218 for cutting the recording material 172 into a prescribed length. For the print head 214, a print head for an ink-jet printer or a thermal printer may be used. Since the printer 170 b is the aforementioned second printer, the printer 170 b can be used for carrying out diagnosis in emergency or checking images for confirmation, though the image quality thereof is not so high as that of the first printer. Also, the printer 170 b may be used for printing the character information of image capturing conditions, the character information of patient information, the character information of positional information based on GPS, and the like. Meanwhile, for the printer 170 a of the radiation source device 18, the structure in the aforementioned printer 170 b of the cassette 12 may be used.

A preparatory procedure using the cassette 12 and the radiation source device 18, as well as operations of the first radiographic apparatus 10A to capture radiographic images, shall be described below.

First, the operator 38 performs an operation to ready the first radiographic apparatus 10A for capturing radiographic images at a site where the first radiographic apparatus 10A has been carried. The operator 38 operates the operating unit 40 of the mobile terminal 42 (or the operating unit 1008 of the console 1004) in order to register image capturing conditions including subject information (e.g., SID) of the subject 50 to be imaged.

In this case, the operator 38 operates the operating unit 40 while the mobile terminal 42 either is detached from or placed within the recess 54. If the body region to be imaged and an image capturing method are known, then the operator 38 also operates the operating unit 40 in order to register the body region and the image capturing method as image capturing conditions. If details of the subject 50 are already known before the operator 38 carries the first radiographic apparatus 10A to the imaging site, then the operator 38 may register the subject information including such details using the mobile terminal 42, which is located at the data center, e.g., medical organization or the like, where the subject 50 is being treated.

In this way, in a case where the operator 38 operates the operating unit 40 of the mobile terminal 42 (or the operating unit 1008 of the console 1004), the registered image capturing conditions, including subject information of the subject 50, are sent from the transceiver 98 of the mobile terminal 42 to the transceiver 94 of the cassette 12 by way of wireless communications, whereupon the image capturing conditions are registered in the cassette controller 92.

In a case where the operator 38 presses the unlocking button 34, the hook 64 is displaced toward the side wall 52 d against the resiliency of the spring 60 until the hook 64 is brought out of engagement with the edge of the through hole 66.

In a case where the operator 38 detaches the radiation source device 18 from the cassette 12 while the hook 64 does not engage with the edge of the through hole 66, i.e., while the operator 38 presses the unlocking button 34, then the connection terminal 68 a becomes disengaged from the connection terminal 70 a, and the connection terminal 68 b becomes disengaged from the connection terminal 70 b, thereby releasing the radiation source device 18 and the cassette 12 from each other.

The operator 38 sets the imaging distance and then brings the mark 130, which is displayed on the irradiated surface 20, into alignment with the central position 126 of the guide lines 22. Thereafter, the operator 38 places and positions the subject 50 between the irradiated surface 20 and the radiation source device 18.

The operator 38 moves the radiation source device 18, whereby the ribbon 76 is reeled out from the tape measure 72 until the actual reeled-out length of the ribbon 76 reaches the reeled-out length 11 that depends on the SID.

The ribbon 76 is reeled out from the tape measure 72 until the actual reeled-out length of the ribbon 76 reaches the reeled-out length 11, in accordance with either of the two processes described below.

According to the first process, the SID determining unit 168 automatically determines whether or not the actual reeled-out length of the ribbon 76 has reached the reeled-out length 11. Therefore, the operator 38 is able to reel out the ribbon 76 from the tape measure 72 until the actual reeled-out length of the ribbon 76 reaches the reeled-out length 11 that depends on the SID.

In the first process, the rotary encoder 78 detects the actual reeled-out length of the ribbon 76, and based on the detected reeled-out length, the SID determining unit 168 calculates the imaging distance between the focus point 122 and the position 124 in a case where the radiation source device 18 is tentatively placed over the irradiated surface 20 in accordance with the present reeled-out length of the ribbon 76.

If the imaging distance agrees with the SID, then the SID determining unit 168 controls the display unit 36 via the transceivers 94, 98 to display information representing the reeled-out length of the ribbon 76, and also to display information representing that the imaging distance agrees with the SID. If the imaging distance does not agree with the SID, then the SID determining unit 168 controls the display unit 36 via the transceivers 94, 98 to display information representing the difference between the present reeled-out length and the reeled-out length 11, and also to display information representing that the imaging distance does not agree with the SID.

The first process allows the operator 38 to set the imaging distance easily, because the operator 38 may reel out the ribbon 76 from the tape measure 72 according to the information displayed on the display unit 36.

According to the second process, the reeled-out length 11 already is known, and the operator 38 reels out the ribbon 76 from the tape measure 72, while observing the graduations 74, until the present reeled-out length reaches the reeled-out length 11.

After the ribbon 76 has been reeled out from the tape measure 72 until the present reeled-out length reaches the reeled-out length 11 that depends on the SID, the operator 38 moves the radiation source device 18 so as to confront (i.e., be placed in a facing relationship with) the irradiated surface 20.

In this case, the radiation source controller 102 controls the laser pointer 104 to apply a laser beam 128 to the irradiated surface 20. The crisscross mark 130, which represents the center of a range within which the irradiated surface 20 is irradiated with radiation 46, is displayed on the irradiated surface 20. The operator 38 positionally adjusts the radiation source device 18 until the mark 130 and the central position 126 are aligned with each other.

After having adjusted the position of the radiation source device 18 until the mark 130 and the central position 126 are aligned with each other, the operator 38 places or positions the subject 50 on the irradiated surface 20, so that the center of a body region of the subject 50 to be imaged is aligned with the central position 126, i.e., is aligned with the position of the mark 130.

After the above positional adjustment has been made, the radiation source device 18 is secured at the adjusted position by a holder, not shown, for example.

At a site such as a disaster site, due to limited space availability, the first radiographic apparatus 10A may not be able to capture radiographic images with the desired SID. Therefore, the cassette controller 92 may recalculate image capturing conditions based on a new SID, which is different from the desired SID, and store the recalculated image capturing conditions together with the new SID in association with image data, or transmit the new SID and/or the recalculated image capturing conditions via a network to a data center for confirmation.

After the subject 50 has been positioned, the operator 38 turns on the exposure switch 48 to begin capturing radiographic images of the subject 50.

In a case where the exposure switch 48 is turned on, the radiation source controller 102 sends a request for image capturing conditions to the cassette controller 92 by way of wireless communications. Based on such a request, the cassette controller 92 sends the image capturing conditions (control signals) with respect to the body region of the subject 50 to be imaged to the radiation source device 18. In a case where the radiation source controller 102 receives the image capturing conditions, the radiation source controller 102 controls the laser pointer 104 in order to stop emitting the laser beam 128, and controls the radiation source 44 to apply radiation 46 at a predetermined dose to the subject 50.

In the radiation source 44, the rotating mechanism 106 is controlled by the radiation source controller 102 in order to rotate the rotational shaft 108 and the rotary anode 110. The power supply 118 applies a negative voltage to the field-electron-emission-type electron source 116, and the power supply 120 applies a voltage between the rotary anode 110 and the cathode 114, based on electric power supplied from the battery unit 304. The field-electron-emission-type electron source 116 emits electrons, which are accelerated by the voltage applied between the rotary anode 110 and the cathode 114, and the electrons bombard the target layer 112. The surface of the target layer 112, which is bombarded with electrons, emits radiation 46 from the focus point 122, the intensity of which depends on the applied electrons.

While the subject 50 is irradiated with radiation 46 for a given irradiation time based on the image capturing conditions, the radiation 46 passes through the subject 50 and reaches the radiation detector 86 of the cassette 12.

Since the radiation detector 86 is of an indirect conversion type, the scintillator of the radiation detector 86 emits visible light having an intensity that depends on the intensity of the radiation 46, and the pixels 132 of the photoelectric conversion layer 138 convert the visible light into electric charges and store the electric charges. The electric charges stored by the pixels 132, which are representative of a radiographic image of the subject 50, are read from the pixels 132 according to address signals, which are supplied from the address signal generator 162 of the cassette controller 92 to the line scanning driver 142 and the multiplexer 144.

More specifically, in response to an address signal supplied from the address signal generator 162, the address decoder 146 of the line scanning driver 142 outputs a selection signal in order to select one of the switches SW1, which supplies the control signal Von to the gates of the TFTs 140 that are connected to the gate line 134 corresponding to the selected switch SW1. In response to address signals supplied from the address signal generator 162, the address decoder 152 of the multiplexer 144 outputs selection signals to successively turn on the switches SW2 so as to switch between the signal lines 136, for thereby reading through the signal lines 136 the electric charges stored in the pixels 132 that are connected to the selected gate line 134.

The electric charges, which are read from the pixels 132 connected to the selected gate line 134, are amplified respectively by the amplifiers 148, sampled by the sample and hold circuits 150, and supplied to the multiplexer 144. Based on the supplied electric charges, the multiplexer 144 generates and supplies radiographic image signals to the A/D converter 154, which converts the radiographic image signals into digital signals. Digital signals representative of the radiographic image information are stored in the image memory 164 of the cassette controller 92.

Similarly, the address decoder 146 of the line scanning driver 142 successively turns on the switches SW1 so as to switch between the gate lines 134 according to the address signals supplied from the address signal generator 162. Electric charges stored in the pixels 132 connected to the successively selected gate lines 134 are read through the signal lines 136, processed by the multiplexer 144, and converted into digital signals by the A/D converter 154. The digital signals are stored in the image memory 164 of the cassette controller 92.

Radiographic image information represented by the digital signals stored in the image memory 164 is transmitted through the transceiver 94 to the mobile terminal 42 by way of wireless communications. Radiographic image information transmitted to the mobile terminal 42 is received by the transceiver 98, and is transmitted from the transceiver 98 to the display unit 36, which displays a radiographic image based on the radiation image information, as shown in FIG. 18. The operator 38 can determine whether or not the body region of the subject 50 to be imaged has been appropriately imaged by confirming the radiographic image displayed on the display unit 36.

For example, if the radiographic image displayed on the display unit 36 does not include the body region of the subject 50 to be imaged, then the operator 38 judges that the subject 50 has not been appropriately imaged, and captures another radiographic image of the subject 50. In this case, using the mobile terminal 42, the operator 38 updates the number of captured images in the image capturing conditions, by incrementing the number with the number of recaptured images.

The radiographic image displayed on the display unit 36 may be of a quality that is sufficient enough to determine whether or not the subject 50 has been appropriately imaged. The displayed radiographic image may either be a radiographic image represented by the radiographic image information stored in the image memory 164, an image of raw data, or a relatively low resolution processed image.

The battery controller 306 will be described below with reference to FIGS. 20 through 25.

As shown in FIG. 20, the battery controller 306 comprises a memory 330, an electric power supply activator 336 for activating an electric power controller 334 according to supply timing conditions, the electric power controller 334 for enabling supply of electric power between the batteries 308 (see FIG. 19) of the devices that are connected in a wired or wireless fashion, an electric power supply limiter 338 for limiting the supply of electric power by the electric power controller 334 during the period in which a radiographic image is being captured, and a pause processor 340 for temporarily pausing the electric power controller 334 when a necessary image capturing process is completed or when the supply of electric power is completed.

The memory 330 stores ID information for identifying the devices incorporating the battery controller 306, i.e., the cassette 12, the radiation source device 18, etc., and also stores various conditions. The memory 330 also temporarily stores various table information, which may be entered via a network, the mobile terminal 42, etc.

Turning on the power supply, the electric power supply activator 336 is activated. If the supply timing conditions stored in the memory 330 are free of timing controls, then the electric power supply activator 336 of a device whose electric power supply switch has been operated activates the corresponding electric power controller 334 based on operation of the electric power supply switch. The electric power supply activator 336 may activate the electric power controller 334 without waiting for the electric power supply switch to be operated. In such a case, if an interlock process is not performed, then the electric power controllers 334 of all the devices whose power supply is turned on are activated, thus tending to cause processing operations to interfere with each other. Therefore, the electric power supply activator 336 of each of the devices refers to interlock information registered in the memory 330, i.e., the ID of the radiation source device 18 or the cassette 12 to be used in a preset image capturing process, and only the electric power supply activator 336 of a device whose ID is identical to the ID of the interlock information activates the corresponding electric power controller 334. Thus, for example, only the electric power controller 334 of the radiation source device 18 that is used in the preset image capturing process is operated, while interference from the other devices is prevented.

If the supply timing conditions indicate supply of electric power before capturing of radiographic images, then the electric power controller 334 is activated based on the image capturing conditions (order) that are input from the mobile terminal 42. In this case, only the electric power supply activator 336 of a device having an ID identical to that of the ID of the radiation source device 18 or the cassette 12 to be used to capture radiographic images, which is registered in advance in the image capturing conditions, activates the corresponding electric power controller 334. If the supply timing conditions indicate supply of electric power after capturing of radiographic images, then the electric power controller 334 is activated based on an image capture completion signal supplied from an image capture completion determiner 386 (see FIG. 21). In this case as well, only the electric power supply activator 336 of a device having an ID identical to that of the ID of the radiation source device 18 or the cassette 12 to be used to capture radiographic images, which is registered in advance in the image capturing conditions, activates the corresponding electric power controller 334.

The electric power controller 334 is available in different configurations according to two specific examples, i.e., a first specific example and a second specific example. According to the first specific example, as shown in FIG. 21, the battery 308 of the radiation source device 18 supplies electric power to the battery 308 of the cassette 12, or the battery 308 of the radiation source device 18 controls supply of electric power to the battery 308 of the cassette 12. As shown in FIG. 21, the electric power controller 334 according to the first specific example comprises, as functional components thereof, a device connection detector 360, a cassette selector activator 362, a cassette selector 364, an integrated supply activator 366, an integrated supply 368, an electric power supply route setting unit 370, an amount-of-supplied-electric-power setting unit 372, an electric power supply controller 374, a remaining level detector 376, an image capture interruption instructing unit 378, a counter 380, a re-supply instructing unit 382, an image capture permission instructing unit 384, an image capture completion determiner 386, and an electric power supply completion output unit 388.

According to the second specific example, the electric power controller 334 controls supply of electric power such that the remaining levels of electric power stored in the batteries 308 of the connected devices are utilized flexibly between the connected devices, based on preset battery charging conditions and image capturing conditions. As shown in FIG. 22, the electric power controller 334 according to the second specific example comprises, in addition to the functional components as described above, an electric power manager 390 and functional components ancillary to the electric power manager 390, which include a remaining level prediction updater 392, a usage history updater 394, a remaining level information transfer unit 396, and a usage history transfer unit 398.

Flexible utilization of the remaining levels of electric power stored in the batteries 308 between the connected devices implies at least the following aspects:

(1) One or more devices, the batteries of which store an excessive remaining level of electric power, supply electric power to a device whose battery stores a remaining level of electric power that is not sufficient to capture radiographic images.

(2) One or more devices, which are not used to capture radiographic images, supply electric power required to capture radiographic images to the aforesaid device, which is used to capture radiographic images.

(3) One or more devices, which are not used to capture radiographic images, supply electric power required to capture radiographic images to the aforesaid device, which is used to capture radiographic images, while increasing the remaining level of electric power in the battery of the aforesaid device, i.e., the amount of electric power held by the aforesaid device, up to at least a level required to capture radiographic images.

As shown in FIG. 22, the electric power controller 334 limits supply of electric power during a period in which the electric power controller 334 is supplied with a supply limit signal, which is input thereto from the electric power supply limiter 338. Limiting supply of electric power refers to stopping supply of electric power, reducing the amount of electric power supplied per unit time, or controlling supply of electric power in a stepwise manner. To stop supply of electric power, as shown in FIG. 19, the electric power controller 334 may output a stop signal to the electric power supply controller 374, thereby causing the electric power supply controller 374 to relay-control the first through fifth switchers 314 a through 314 e in order to change to neutral positions thereof, which are neither input positions nor output positions, for example. In order to reduce the amount of electric power supplied per unit time, the electric power controller 334 may output a supplied-amount reduction signal to the electric power supply controller 374, thereby causing the electric power supply controller 374 to reduce the amount of electric power supplied per unit time to a preset level. In order to control the supply of electric power in a stepwise manner, as described later, the electric power controller 334 may stop supplying electric power while electric charges are being stored in the pixels in the cassette 12 and are converted from analog signals into digital signals, supply a small amount of electric power while image data are being transferred, and supply a large amount of electric power during an idling period after transferring of the image data is completed. The electric power controller 334 stops controlling supply of electric power based on a pause signal, which is input from the pause processor 340, and waits to be activated at a subsequent time by the electric power supply activator 336.

According to the first specific example, as shown in FIG. 19, for example, the device connection detector 360 detects whether the device (radiation source or cassette) is connected to at least one of the first energy input/output unit 300 and the second energy input/output unit 302 in a wired or wireless fashion. A wireless connection is detected by, for example, an obstacle sensor such as an ultrasonic sensor or the like, which determines whether the device (radiation source device 18 or cassette 12) has entered into an area in which the device can be supplied with electric power wirelessly from the first energy input/output unit 300 and the second energy input/output unit 302. As shown in FIG. 23, the cassette selector activator 362 activates the cassette selector 364 if a condition concerning a route, from among battery charging conditions stored in the memory 330, represents only supply of electric power from one cassette 12 to the radiation source device 18, the aforesaid device is the radiation source device 18, and connection of a plurality of cassettes 12 to the radiation source device 18 is detected.

The cassette selector 364 comprises a cassette ID acquirer 400, a cassette information acquirer 402, and a selector 404.

The cassette ID acquirer 400 sends a transfer request for requesting that the cassettes 12, which are connected to the radiation source device 18, transfer IDs thereof. The cassettes 12 output IDs to the radiation source device 18 based on the transfer request. The cassette ID acquirer 400 acquires the IDs and stores the IDs in the memory 330.

The cassette information acquirer 402 acquires cassette information tables, which contain information concerning defective pixels, etc., and usage history tables corresponding to the acquired IDs via the network.

The selector 404 selects a cassette 12 that matches selecting conditions from among the connected cassettes 12 based on the selecting conditions, the acquired cassette information tables, and the acquired usage history tables, which are stored in the memory 330. The selector 404 then outputs the ID of the selected cassette 12 to the electric power supply route setting unit 370.

The selecting conditions for selecting a cassette 12 include:

(1-a) a large-size cassette 12;

This condition serves the purpose of discharging electric power from a large-size cassette 12 in a special environment where no large-size cassette 12 is used. The size of a cassette 12 is determined based on size information that is recorded in the cassette information table.

(1-b) a small-size cassette 12;

This condition serves the purpose of preferentially discharging electric power from a cassette 12 that is less versatile.

(1-c) a cassette 12 with many defective pixels;

This condition serves the purpose of preferentially discharging electric power from a cassette 12 that is less frequently used, thereby preventing the cassette 12 from becoming disabled substantially simultaneously. The number of defective pixels is determined based on information concerning defective pixels recorded in the cassette information table. The information concerning defective pixels, which is recorded in the cassette information table, is regularly or irregularly updated upon calibration or the like, for example.

(1-d) a cassette 12 with a small imaging area;

The size of an imaging area is calculated from information concerning defective pixels, which is recorded in the cassette information table, particularly positional information about the defective pixels.

(1-e) a cassette 12 with a highly deteriorated battery 308;

(1-f) a cassette 12 with a lowly deteriorated battery 308;

The level of deterioration of the battery 308 is determined based on the number of times that the cassette 12 has been used, which is recorded in the cassette information table.

(1-g) a cassette 12 that has been used many times;

The number of times that the cassette 12 has been used is determined based on a counted number of times that the cassette 12 has been used, which is recorded in the cassette information table, or based on information concerning an accumulated radiation dose, which is recorded in the cassette information table.

(1-h) a cassette 12 with a small remaining built-in memory capacity;

The remaining built-in memory capacity is determined based on a reply, which is sent from the cassette controller 92 in response to an inquiry as to the remaining built-in memory capacity sent to the cassette controller 92.

(1-i) a cassette 12 that is positioned a small distance from the radiation source device 18;

This condition serves the purpose of selecting a cassette 12 that can easily supply electric power over a small distance, thereby reducing the burden on the circuits involved.

The distance from the radiation source device 18 to the cassette 12 is determined based on the information concerning present positions of the cassettes 12 acquired via GPS, or distance information from a range sensor such as an ultrasonic sensor, a three-dimensional magnetic sensor, or the like.

As shown in FIG. 24, the integrated supply activator 366 activates the integrated supply 368 if a condition concerning a route, from among the battery charging conditions stored in the memory 330, represents only supply of electric power from a plurality of cassettes 12 to the radiation source device 18, the aforesaid device is the radiation source device 18, and connection of a plurality of cassettes 12 to the radiation source device 18 is detected.

The integrated supply 368 comprises a cassette ID acquirer 400, a cassette information acquirer 402, and a weighting setting unit 406.

The cassette ID acquirer 400 sends a transfer request for requesting that cassettes 12 connected to the radiation source device 18 transfer IDs thereof. The cassettes 12 output IDs to the radiation source device 18 based on the transfer request. The cassette ID acquirer 400 acquires the IDs and stores the IDs in the memory 330.

The cassette information acquirer 402 acquires cassette information tables, which contain information concerning defective pixels, etc., and usage history tables corresponding to the acquired IDs via the network.

The weighting setting unit 406 sets weighting coefficients for respective amounts of electric power to be supplied from the cassettes 12 to the radiation source device 18, based on integrating conditions, the acquired cassette information tables, and the acquired usage history tables, which are stored in the memory 330. The weighting setting unit 406 then outputs the set weighting coefficients, together with corresponding ID information, to the amount-of-supplied-electric-power setting unit 372.

The integrating conditions include:

(2-a) The amount of supplied electric power is sorted depending on the amount of defective pixels;

As the number of defective pixels becomes greater, the weighting setting unit 406 sets a weighting coefficient for increasing the amount of supplied electric power. Conversely, as the number of defective pixels becomes smaller, the weighting setting unit 406 sets a weighting coefficient for reducing the amount of supplied electric power.

(2-b) The amount of supplied electric power is sorted depending on the imaging area;

As the imaging area becomes smaller, the weighting setting unit 406 sets a weighting coefficient for increasing the amount of supplied electric power. Conversely, as the imaging area becomes greater, the weighting setting unit 406 sets a weighting coefficient for reducing the amount of supplied electric power.

(2-c) The amount of supplied electric power is sorted depending on the level of deterioration of the battery 308;

As the level of deterioration of the battery 308 becomes greater, the weighting setting unit 406 sets a weighting coefficient for increasing the amount of supplied electric power. Conversely, as the level of deterioration of the battery 308 becomes smaller, the weighting setting unit 406 sets a weighting coefficient for reducing the amount of supplied electric power.

(2-d) The amount of supplied electric power is sorted depending on the number of times that the cassette 12 has been used;

As the number of times that the cassette 12 has been used becomes greater, the weighting setting unit 406 sets a weighting coefficient for increasing the amount of supplied electric power. Conversely, as the number of times that the cassette 12 has been used is smaller, the weighting setting unit 406 sets a weighting coefficient for reducing the amount of supplied electric power.

(2-e) The amount of supplied electric power is sorted depending on the remaining built-in memory capacity;

As the amount of supplied electric power becomes smaller, the weighting setting unit 406 sets a weighting coefficient for increasing the amount of supplied electric power. Conversely, as the amount of supplied electric power becomes greater, the weighting setting unit 406 sets a weighting coefficient for reducing the amount of supplied electric power.

(2-f) The amount of supplied electric power is sorted depending on the distance to the radiation source device 18.

As the distance to the radiation source device 18 becomes smaller, the weighting setting unit 406 sets a weighting coefficient for increasing the amount of supplied electric power. Conversely, as the distance to the radiation source device 18 becomes greater, the weighting setting unit 406 sets a weighting coefficient for reducing the amount of supplied electric power.

Then, the electric power supply route setting unit 370 sets a route for supply of electric power based on a condition concerning the route from among the battery charging conditions stored in the memory 330. For example, the electric power supply route setting unit 370 sets a route from the radiation source device 18 to the cassette 12, or a route from the cassette 12 to the radiation source device 18. If the electric power supply route setting unit 370 is supplied with an ID from the cassette selector 364, then the electric power supply route setting unit 370 sets a route from the cassette 12 to the radiation source device 18 corresponding to the ID. If the electric power supply route setting unit 370 is supplied with a plurality of IDs from the integrated supply 368, then the electric power supply route setting unit 370 sets routes from the cassettes 12 to the radiation source device 18 corresponding to such IDs. Route information representing the set IDs is displayed on the display unit 1010 of the console 1004 or a display screen of the mobile terminal 42. The condition concerning the route is descriptive of at least one source of electric power. If the source of electric power is the radiation source device 18, then the radiation source device 18 supplies electric power to the cassette 12. If the source of electric power is the cassette 12, then the cassette 12 supplies electric power to the radiation source device 18. The condition concerning the route can be changed as desired by the mobile terminal 42. If the re-supply instructing unit 382 provides a re-supply instruction, i.e., if the re-supply instructing unit 382 inputs a re-supply instruction signal to the electric power supply route setting unit 370, then the electric power supply route setting unit 370 sets the route for supply of electric power based on battery charging conditions. If the operator 38 intends to additionally charge the battery of another device, e.g., the radiation source device 18 or the cassette 12, then the operator 38 enters the route for supply of electric power to the other device, i.e., a route from the other device to the radiation source device 18 or the cassette 12 that is used to capture radiographic images, or a route from the radiation source device 18 or the cassette 12 that is used to capture radiographic images to the other device, and also enters an amount of electric power to be supplied. Based on the entered route for supply of electric power, the electric power supply route setting unit 370 outputs a supply source instruction signal or a supply destination instruction signal to the electric power supply controller 374 of each device.

The amount-of-supplied-electric-power setting unit 372 sets an amount of electric power to be supplied based on a condition concerning the amount of electric power to be supplied, from among the battery charging conditions. At least items such as a full battery charge, an amount of electric power to be supplied that is required to capture a single radiographic image, etc., can be used as conditions concerning the amount of electric power to be supplied. One of such items, which is selected at present, is applicable as the condition concerning the amount of electric power to be supplied. An item to be applied can be selected as desired by the mobile terminal 42. An amount of electric power to be supplied can be set as a numerical value by the mobile terminal 42. If the amount-of-supplied-electric-power setting unit 372 is supplied with a plurality of IDs and corresponding coefficients from the integrated supply 368, then the amount-of-supplied-electric-power setting unit 372 multiplies the amount of electric power to be supplied by such coefficients in order to set amounts of electric power to be supplied respectively from the cassettes 12 to the radiation source device 18. If the re-supply instructing unit 382 provides a re-supply instruction, then the amount-of-supplied-electric-power setting unit 372 sets an amount of electric power to be supplied based on a condition concerning the amount of electric power to be supplied, from among the battery charging conditions. The amount of electric power to be supplied can also be changed as desired by the mobile terminal 42. If batteries of devices are to be charged as well, then the amount-of-supplied-electric-power setting unit 372 also sets respective amounts of electric power to be supplied in order to charge the batteries, and supplies the set amounts of electric power to be supplied to the electric power supply controllers 374 of each of the respective devices.

As shown in FIG. 19, if a supply source instruction signal is input to the electric power supply controller 374, then the electric power supply controller 374 controls the battery 308 in order to output electric power. If a supply destination instruction signal is input to the electric power supply controller 374, then the electric power supply controller 374 controls the battery 308 in order to receive electric power. Based on a remaining level of electric power in the battery 308, which is detected by the remaining level detector 376, the electric power supply controller 374 controls the battery 308 that is supplied with electric power at a constant charging rate, or controls the battery 308 to supply electric power at the constant discharging rate. Assuming that the amount of electric power to be supplied is small, then the electric power supply controller 374 can quickly charge or discharge the battery 308. If the remaining level of electric power in the battery 308, which is detected by the remaining level detector 376, is insufficient to capture a single radiographic image, then the electric power supply controller 374 outputs an imaging disable signal, which includes the remaining level of electric power and the ID of the aforesaid device. In a case where the supply of electric power to the battery 308 or the supply of electric power from the battery 308 is completed, the electric power supply controller 374 outputs a supply termination signal.

As described above, the remaining level detector 376 detects a remaining level of electric power in the battery 308, and sends a signal representative of the detected remaining level of electric power in the battery 308 to the electric power supply controller 374.

The image capture interruption instructing unit 378, as shown in FIG. 21, outputs a message representing interruption of an image capturing process to the mobile terminal 42, based on an imaging disabled signal input from the electric power supply controller 374.

The counter 380 counts the number of times that the exposure switch 48 has been turned on. The counter 380 resets the count (count=0) based on an image capture completion signal, which is input from the image capture completion determiner 386.

Based on the imaging disabled signal input from the electric power supply controller 374, the re-supply instructing unit 382 outputs a re-supply instruction signal including the preset count of the counter 380, the amount of electric power included in the imaging disabled signal, and the ID of the aforesaid device, respectively, to the electric power supply route setting unit 370, the amount-of-supplied-electric-power setting unit 372, and the electric power manager 390. If electric power is supplied after capturing of radiographic images, since the electric power controller 334 itself is not activated, the re-supply instructing unit 382 of the radiation source device 18 or the cassette 12 that is used to capture radiographic images activates the electric power supply route setting unit 370, the amount-of-supplied-electric-power setting unit 372, and the electric power manager 390, using an interrupt routine for emergency.

If the supply timing conditions recorded in the memory 330 are free of timing controls, or indicate supply electric power before capturing of radiographic images, then the image capture permission instructing unit 384 outputs an image capture permission message to the mobile terminal 42 based on supply termination signals, which are input from the electric power supply controllers 374 of all of the devices to which electric power is supplied.

The image capture completion determiner 386 compares the number of times that radiographic images have been captured in the image capturing conditions with the count of the counter 380, and outputs an image capture completion signal when the number of times that radiographic images have been captured becomes equal to the count.

The electric power supply completion output unit 388 outputs an electric power supply completion signal based on supply termination signals, which are input from the electric power supply controllers 374 of all of the devices to which electric power is supplied.

The electric power supply limiter 338 shown in FIG. 20 determines whether or not a radiographic image of the subject 50 is being captured if the supply timing conditions recorded in the memory 330 include a condition indicating that “the supply of electric power is stopped while a radiographic image is being captured.” If a radiographic image is being captured, then the electric power supply limiter 338 outputs a supply limit signal during the period in which a radiographic image is being captured. More specifically, when the exposure switch 48 is turned on, the electric power supply limiter 338 outputs a supply limit signal. Thereafter, when a predetermined period of time has elapsed, the electric power supply limiter 338 stops outputting the supply limit signal. The electric power controller 334 limits supply of electric power during the period in which the supply limit signal is input thereto.

The period during which the electric power supply limiter 338 outputs the supply limit signal should preferably be any one of a period (storage period) in which radiation 46 having passed through the subject 50 is applied to the radiation detector 86 and converted by a scintillator (not shown) into visible light, and the visible light is converted at each pixel 132 into electric signals that are stored as electric charges (signal charges), a period (reading period) during which the stored electric charges are read, and a period (analog-to-digital conversion period) during which the read electric charges (analog signals) are converted into digital signals by the A/D converter 154, a period which is a combination of the above periods, or a period that includes all the above periods. In the above three periods, the image signals (radiographic image information) are highly susceptible to noise. More specifically, in the storage period and the reading period, since the level of electric charge is very low, the radiographic image information is highly susceptible to noise. In the analog-to-digital conversion period, analog signals are less resistant to noise than digital signals, and any noise added to the analog signals tends to be converted into digital signals and appear in the image data.

The storage period includes a period during which the radiation source 44 emits radiation 46. More specifically, after the storage period has started, the radiation source 44 begins to emit radiation 46 as quickly as possible, and after the radiation source 44 has stopped emitting radiation 46, the stored electric charges are read immediately from the pixels. Any time lag associated with these processes should be reduced as much as possible in order to reduce dark current, and hence increase the quality of radiographic images that are generated. The reading period refers to a period during which the TFTs 140 are turned on, and signals are supplied through the amplifiers 148 to the A/D converter 154. The reading period and the analog-to-digital conversion period occur substantially at the same time, although the reading time starts slightly earlier than the analog-to-digital conversion period.

The period during which the supply limit signal is output should extend from a time when the supply limit signal is output to a time when the radiation source device 18 stops emitting radiation 46, or more preferably reside within the period during which the radiographic image is captured, so that the cassette 12 can detect radiation 46 with high quality. A predicted time, which is required to capture and display a radiographic image, may be preset and used as the period during which the supply limit signal is output. The degree to which the amount of supplied electric power is reduced per unit time may be set experimentally to a value for preventing noise from being added to the radiographic image, or for reducing any added noise to a level that is not detrimental to the quality of the radiographic image.

If the supply timing conditions recorded in the memory 330 are free of timing controls, or indicate supply of electric power before capturing of radiographic images, then the pause processor 340 shown in FIG. 20 outputs a pause signal to the electric power controller 334, based on an image capture completion signal input from an image capture completion determiner 386. If the supply timing conditions recorded in the memory 330 indicate supply of electric power after capturing of radiographic images, then the pause processor 340 outputs a pause signal to the electric power controller 334, based on an electric power supply completion signal input from the electric power supply completion output unit 388.

According to the second specific example, the electric power manager 390 shown in FIG. 22 gives the electric power supply controller 374 information for controlling supply of electric power, such that the remaining levels of electric power stored in the batteries 308 of the devices are utilized flexibly between the devices, based on predesignated battery charging conditions and image capturing conditions. The electric power manager 390 is incorporated in the radiation source device 18 and/or the cassette 12. As shown in FIG. 25, the electric power manager 390 comprises an ID acquirer 410, an information acquirer 412 for acquiring various information, an amount-of-consumed-electric-power predictor 414, and an information updater 416.

The ID acquirer 410 sends a transfer request for requesting the device that incorporates the electric power manager 390 therein and another device that is connected to the device to transfer respective IDs thereof. Based on the transfer request, the devices output their IDs respectively to the electric power manager 390. The ID acquirer 410 acquires the IDs input thereto and registers the acquired IDs in the memory 330. If another radiation source device 18 or another cassette 12, in addition to the radiation source device 18 and the cassette 12 used to capture radiographic images, are connected or are present in an area in which they can be fed wirelessly, then the ID acquirer 410 also acquires IDs of the other radiation source device 18 and the cassette 12.

The information acquirer 412 for acquiring various information acquires present or previous image capturing conditions, which are input via the mobile terminal 42 or the network, remaining level-of-electric-energy information tables corresponding to the IDs, previous image capturing conditions corresponding to the IDs, and usage history tables corresponding to the IDs, and stores such information in the memory 330.

The amount-of-consumed-electric-power predictor 414 calculates amounts of electric power that are consumed by the radiation source device 18 and the cassette 12 used to capture radiographic images, from the battery charging conditions stored in the memory 330 and the present or previous image capturing conditions representative of the number of radiographic images to be captured, mAs values, etc. The amount-of-consumed-electric-power predictor 414 then corrects the calculated amounts of electric power by multiplying the calculated amounts by usage histories of the radiation source device 18 and the cassette 12, i.e., coefficients corresponding to the number of times that the radiation source device 18 and the cassette 12 have been used, thereby predicting amounts of electric power that will be consumed by the radiation source device 18 and the cassette 12 during the present image capturing process, or amounts of electric power consumed by the radiation source device 18 and the cassette 12 in the previous image capturing process. If a re-supply instruction is input from the re-supply instructing unit 382, then the amount-of-consumed-electric-power predictor 414 calculates amounts of electric power to be consumed by the respective devices indicated by the IDs, i.e., the radiation source device 18 and the cassette 12 to be re-supplied with electric power, from image capturing conditions for the image capturing process to be carried out, from which image capturing conditions for radiographic images already captured (indicated by the count) are excluded, which are among the present image capturing conditions representative of the number of radiographic images to be captured, mAs values, etc., and corrects the calculated amounts of electric power by multiplying the calculated amounts by usage histories of the radiation source device 18 and the cassette 12, i.e., coefficients corresponding to the number of times that the radiation source device 18 and the cassette 12 have been used, thereby predicting amounts of electric power that will be consumed by the devices of the IDs in the image capturing process to be carried out.

The information updater 416 subtracts the amount of supplied electric power from the remaining level of electric power of a device serving as an electric power supply source, and adds the amount of supplied electric power to the remaining level of electric power of a device that serves as an electric power supply destination, in the remaining level-of-electric-energy information table. If the re-supply instructing unit 382 outputs a re-supply instruction, then the information updater 416 changes only the remaining levels of electric power of the respective devices indicated by the IDs. A value produced by adding the present amount of supplied electric power to the amount of electric power included in the re-supply instruction signal is recorded in the memory 330. Since this value reflects the amount of electric power from the electric power supply controller 374, an error in the remaining level of electric power, which is represented by only a predicted value, is corrected.

According to the second specific example, because the electric power controller 334 includes the electric power manager 390, the electric power supply route setting unit 370 and the amount-of-supplied-electric-power setting unit 372 operate differently from those of the electric power controller 334 according to the first specific example.

More specifically, the electric power supply route setting unit 370 according to the second specific example sets a route for supply of electric power based on the predicted amount of electric power, and the remaining levels of electric power in the batteries 308 of the radiation source device 18 and the cassette 12 (remaining level-of-electric-energy information tables). Typically, the electric power supply route setting unit 370 sets a route for supplying electric power to a device, the battery of which stores a remaining level of electric power that will almost be eliminated in the present image capturing process. Information concerning the set route is displayed on the display screen of the mobile terminal 42. If the re-supply instructing unit 382 outputs a re-supply instruction, then the electric power supply route setting unit 370 sets routes for supplying electric power to respective devices indicated by the IDs. If the operator 38 intends to supply electric power additionally from other devices, i.e., a radiation source device 18 and a cassette 12 that are not used to capture radiographic images, then the operator 38 enters routes for supplying electric power, and amounts of electric power, from the other devices, i.e., routes for supplying electric power from the other devices to the respective devices indicated by the IDs. If the operator 38 additionally intends to charge a battery using another device, i.e., a radiation source device 18 or a cassette 12, then the operator 38 enters a route for supplying electric power to or from the other device, i.e., a route from the other device to the radiation source device 18 or the cassette 12 that is used to capture radiographic images, or a route from the radiation source device 18 or the cassette 12 that is used to capture radiographic images to the other device, together with the amount of electric power to be supplied, and an order in which such electric power is supplied. Based on the entered route for supplying electric power, the electric power supply route setting unit 370 outputs a supply source instruction signal or a supply destination instruction signal to the electric power supply controller 374 of each of the devices.

The amount-of-supplied-electric-power setting unit 372 according to the second specific example sets the supplied amount of electric power based on the predicted amount of electric power and the remaining levels of electric power in the batteries 308 of the radiation source device 18 and the cassette 12 (remaining level-of-electric-energy information tables). Thus, at most, the predicted amount of electric power is supplied to a device, the battery of which stores a remaining level of electric power, which will almost be eliminated during the present image capturing process. The amount of electric power, which is supplied to such a device, may be one-half or one-third the predicted amount of electric power. The information concerning the set amount of electric power is displayed on a display screen of the mobile terminal 42. The set amount of electric power can also be changed as desired by the mobile terminal 42. If the operator 38 additionally intends to charge a battery, then the amount-of-supplied-electric-power setting unit 372 also sets the amount of electric power to be supplied, so as to additionally charge the battery. The amount of electric power predicted based on previous image capturing conditions is supplied in order to supplement the amount of electric power consumed in the previous image capturing process. If the re-supply instructing unit 382 outputs a re-supply instruction, then the amount-of-supplied-electric-power setting unit 372 sets the amount of electric power to equal the predicted amount of electric power. The set amount of electric power can be changed as desired by the mobile terminal 42. If the operator 38 additionally intends to charge a battery, then the amount-of-supplied-electric-power setting unit 372 also sets an amount of electric power to be supplied, so as to additionally charge the battery. The set amount of electric power then is supplied to the electric power supply controller 374 of the corresponding device.

Among functional components that are ancillary to the electric power manager 390, the remaining level prediction updater 392 shown in FIG. 22 functions, assuming that the supply timing conditions recorded in the memory 330 indicate supply of electric power before capturing of radiographic images. Each time that the operator 38 turns on the exposure switch 48, the remaining level prediction updater 392 updates, by way of subtraction, the remaining levels of electric power stored in the batteries that are recorded in the remaining level-of-electric-energy information tables, i.e., the remaining levels of electric power stored in the batteries 308 of the radiation source device 18 and the cassette 12, which are used to capture radiographic images. More specifically, with respect to the radiation source device 18 and the cassette 12, the remaining level prediction updater 392 calculates amounts of electric power consumed in order to capture radiographic images based on the image capturing conditions and the usage history tables, and subtracts the calculated amounts of electric power from the remaining levels of electric power stored in the batteries 308 of the radiation source device 18 and the cassette 12, which are recorded in the remaining level-of-electric-energy information tables.

The usage history updater 394 adds to the usage counts recorded in the usage history tables the number of times that the exposure switch 48 has been turned on, i.e., the number of times that the radiation source device 18 and the cassette 12 have been used.

If the supply timing conditions recorded in the memory 330 indicate supply of electric power before capturing of radiographic images, then the remaining level information transfer unit 396 shown in FIG. 22 transfers the remaining level-of-electric-energy information tables via the network to the database of a data center, such as a medical organization or the like for updating, based on an image capture completion signal input from the image capture completion determiner 386. If the supply timing conditions recorded in the memory 330 indicate supply of electric power after capturing of radiographic images, then the remaining level information transfer unit 396 transfers the remaining level-of-electric-energy information tables via the network to the database of the data center for updating, based on an electric power supply completion signal input from the electric power supply completion output unit 388.

If the supply timing conditions recorded in the memory 330 indicate supply of electric power before capturing of radiographic images, then the usage history transfer unit 398 transfers the usage history tables via the network to the database of the data center for updating, based on an image capture completion signal input from the image capture completion determiner 386. If the supply timing conditions recorded in the memory 330 indicate supply of electric power after capturing of radiographic images, then the usage history transfer unit 398 transfers the usage history tables via the network to the database of the data center for updating, based on an electric power supply completion signal input from the electric power supply completion output unit 388.

The first mobile apparatus 1000A basically is constructed as described above. Operations of the first mobile apparatus 1000A will be described below with reference to the flowcharts shown in FIGS. 26 through 32.

First, an operation sequence of the first mobile apparatus 1000A, if the supply timing conditions are free of timing controls, will be described below with reference to the flowcharts shown in FIGS. 26 and 27.

The operator 38 moves the cart unit 1002 toward a subject 50 whose radiographic images are to be captured. Then, the operator 38 takes out the first radiographic apparatus 10A from the cart unit 1002, and separates the radiation source device 18 from the cassette 12. Thereafter, the radiation source device 18 is attached to the distal end 1006 a of the arm unit 1006. If recumbent image capturing is to be carried out, for example, the cassette 12 is disposed between the subject 50 and a bed 1040 or a sheet (blanket etc.). Then, the operator 38 turns on an electric power supply switch (ON operation). The ON operation of the electric power supply switch includes the clicking of the left button of a mouse on an icon representing an electric power supply switch shown on the display unit 1010 of the console 1004. Alternatively, the ON operation may be performed using an operation switch on the cart unit 1002 that is dedicated for electric power supply operation.

In step S1, the electric power controller 334 is activated based on operation of the electric power supply switch. The electric power supply activator 336 may also activate the electric power controller 334 by a supply instruction of electric power from another communication device, without operation of the electric power supply switch by the operator 38. In this case, the electric power supply activator 336 of each of the devices refers to interlock information registered in the memory 330, i.e., an ID of the radiation source device 18 or the cassette 12 that is used in a predesignated image capturing process, and only the electric power supply activator 336 of the device having an ID is identical to that of the interlock information activates the corresponding electric power controller 334.

In step S2, the device connection detector 360 detects whether or not the device, i.e., the radiation source device 18 or the cassette 12, is connected to the first energy input/output unit 300 or to the second energy input/output unit 302.

After the device connection detector 360 has detected the connection in step S2, the cassette selector activator 362 determines whether or not conditions are satisfied for activating the cassette selector 364 in step S3. More specifically, the cassette selector activator 362 activates the cassette selector 364 if a condition concerning a route, from among the battery charging conditions stored in the memory 330, represents only supply of electric power from one cassette 12 to the radiation source device 18, the aforesaid device is the radiation source device 18, and connection of a plurality of cassettes 12 to the radiation source device 18 is detected.

In step S4, the cassette selector 364 selects a cassette 12 that matches the selecting conditions from among the connected cassettes 12, based on a plurality of IDs that are acquired by the cassette ID acquirer 400, selecting conditions stored in the memory 330, and the cassette information tables and the usage history tables, which are acquired by the cassette information acquirer 402. The cassette selector 364 then outputs the ID of the selected cassette 12 to the electric power supply route setting unit 370.

After step S4, or if the cassette selector activator 362 judges that conditions are not satisfied for activating the cassette selector 364 in step S3, control proceeds to step S5, during which the integrated supply activator 366 determines whether conditions are not satisfied in order to activate the integrated supply 368. More specifically, the integrated supply activator 366 activates the integrated supply 368 if a condition concerning a route, from among the battery charging conditions stored in the memory 330, represents only supply of electric power from a plurality of cassettes 12 to the radiation source device 18, the aforesaid device is the radiation source device 18, and connection of a plurality of cassettes 12 to the radiation source device 18 is detected.

In step S6, the integrated supply 368 sets weighting coefficients for the amounts of electric power to be supplied from the cassettes 12 to the radiation source device 18 based on a plurality of IDs that are acquired by the cassette ID acquirer 400, integrating conditions stored in the memory 330, the cassette information tables, and the usage history tables, which are acquired by the cassette information acquirer 402. The integrated supply 368 then outputs the set weighting coefficients to the corresponding amount-of-supplied-electric-power setting unit 372.

After step S6, or if the integrated supply activator 366 judges that conditions are not satisfied for activating the integrated supply 368 in step S5, then control proceeds to step S7, during which the electric power supply route setting unit 370 sets a route for supply of electric power, based on conditions concerning the route from among the battery charging conditions stored in the memory 330. For example, the electric power supply route setting unit 370 sets a route from the radiation source device 18 to the cassette 12, or a route from the cassette 12 to the radiation source device 18. If the electric power supply route setting unit 370 is supplied with an ID from the cassette selector 364, then the electric power supply route setting unit 370 sets a route from the cassette 12 identified by the ID to the radiation source device 18. If the electric power supply route setting unit 370 is supplied with a plurality of IDs from the integrated supply 368, then the electric power supply route setting unit 370 sets multiple routes from the cassettes 12 identified by the IDs to the radiation source device 18. Thereafter, the electric power supply route setting unit 370 outputs information concerning the set route (route information) to the electric power supply controller 374. More specifically, based on the set route for supply of electric power, the electric power supply route setting unit 370 outputs a supply source instruction signal, or a supply destination instruction signal, to the electric power supply controller 374 of each device. For example, it is assumed that the first energy input/output unit 300 of the radiation source device 18 is connected to the first energy input/output unit 300 of the cassette 12. If the set route is a route for supplying electric power from the radiation source device 18 to the cassette 12, then the electric power supply route setting unit 370 outputs a supply source instruction signal to the electric power supply controller 374 of the radiation source device 18, and further outputs a supply destination instruction signal to the electric power supply controller 374 of the cassette 12. If the set route is a route for supplying electric power from the cassette 12 to the radiation source device 18, then the electric power supply route setting unit 370 outputs a supply destination instruction signal to the electric power supply controller 374 of the radiation source device 18, and further outputs a supply source instruction signal to the electric power supply controller 374 of the cassette 12.

In step S8, the amount-of-supplied-electric-power setting unit 372 sets an amount of electric power to be supplied (supplied amount of electric power) based on a condition concerning the amount of electric power to be supplied, from among the battery charging conditions. For example, the amount-of-supplied-electric-power setting unit 372 sets an amount of electric power to be supplied for a full battery charge, or for capturing a single radiographic image. If the amount-of-supplied-electric-power setting unit 372 is supplied with a plurality of IDs and corresponding coefficients from the integrated supply 368, then the amount-of-supplied-electric-power setting unit 372 multiplies the amount of electric power to be supplied by such coefficients in order to set respective amounts of electric power to be supplied to the radiation source device 18 from the respective cassettes 12. The amount-of-supplied-electric-power setting unit 372 outputs information concerning the set amounts of electric power to be supplied to the electric power supply controllers 374 of the corresponding devices.

In step S9, if the electric power supply controller 374 is supplied with a supply source instruction signal, then the electric power supply controller 374 controls the battery 308 in order to output electric power. Further, if the electric power supply controller 374 is supplied with a supply destination instruction signal, then the electric power supply controller 374 controls the battery 308 so as to be supplied with electric power. In a case where supply of electric power to the battery 308 or supply of electric power from the battery 308 is completed, then the electric power supply controller 374 outputs a supply termination signal.

In step S10, the electric power supply completion output unit 388 outputs an electric power supply completion signal based on supply termination signals, which are input from the electric power supply controllers 374 of all of the devices to which electric power has been supplied.

In step S11, the image capture permission instructing unit 384 outputs a message representative of permission to capture an image to the console 1004 and the mobile terminal 42, based on the electric power supply completion signal input from the electric power supply completion output unit 388.

In step S12, the operator 38 prepares the first mobile apparatus 1000A for capturing radiographic images at a site where the first mobile apparatus 1000A has been carried. This preparatory procedure has been described in detail above, and will not be described below.

If the subject 50 is positioned during the preparatory procedure, control proceeds to step S13 shown in FIG. 27, in which the operator 38 turns on the exposure switch 48 to begin capturing radiographic images of the subject 50. In this case, the counter 380 updates the count by incrementing the count by +1.

When the operator 38 turns on the exposure switch 48 in step S13, then in step S14, the electric power supply limiter 338 outputs a supply limit signal to the electric power controller 334 during the aforementioned period. During the period in which the electric power controller 334 is supplied with the supply limit signal, the electric power controller 334 temporarily interrupts the operation thereof to supply electric power.

In step S15, the electric power controller 334 determines whether or not electric power needs to be re-supplied, based on whether the electric power supply controller 374 of any device has output an imaging disabled signal. More specifically, if the remaining level of electric power stored in the battery 308 of the radiation source device 18 or the cassette 12 is insufficient to capture a single radiographic image, then the electric power supply controller 374 outputs an imaging disabled signal, including the remaining level of electric power and the ID of the aforesaid device to the re-supply instructing unit 382, for thereby requesting the re-supply instructing unit 382 to re-supply electric power.

If the electric power controller 334 judges that electric power needs to be re-supplied, then control proceeds to step S16, in which the image capture interruption instructing unit 378 outputs a message indicating interruption of image capturing to the console 1004 and the mobile terminal 42. The console 1004 and the mobile terminal 42 display a message on the display unit 1010 and a display screen thereof, respectively, and preferably output an alarm sound, for prompting the operator 38 to interrupt the image capturing process.

Thereafter, in step S17, the re-supply instructing unit 382 outputs a re-supply instruction signal to the electric power supply route setting unit 370, as well as to the amount-of-supplied-electric-power setting unit 372.

In step S18, the electric power supply route setting unit 370 sets a route for re-supplying electric power (re-supply route) based on the battery charging conditions, and based on the set re-supply route, outputs a supply source instruction signal or a supply destination instruction signal to the electric power supply controller 374 of each device.

In step S19, the amount-of-supplied-electric-power setting unit 372 sets an amount of electric power to be re-supplied (amount of re-supplied electric power) based on a condition concerning the supplied amount, from among the battery charging conditions, and outputs information concerning the set amount of re-supplied electric power to the electric power supply controller 374 of the corresponding device.

In step S20, if the electric power supply controller 374 is supplied with a supply source instruction signal, then the electric power supply controller 374 controls the battery 308 in order to output electric power. Further, if the electric power supply controller 374 is supplied with a supply destination instruction signal, then the electric power supply controller 374 controls the battery 308 so as to be supplied with electric power. In a case where supply of electric power to the battery 308, or supply of electric power from the battery 308 is completed, the electric power supply controller 374 outputs a supply termination signal.

In step S21, the electric power supply completion output unit 388 outputs an electric power supply completion signal, based on supply termination signals that are input from the electric power supply controllers 374 of all of the devices to which electric power is re-supplied.

In step S22, the image capture permission instructing unit 384 outputs a message representing permission to capture an image to the mobile terminal 42, based on the electric power supply completion signal input from the electric power supply completion output unit 388. Thereafter, control returns to step S13 shown in FIG. 27 and steps subsequent thereto.

If the electric power controller 334 judges that no electric power needs to be re-supplied in step S15, then control proceeds to step S23, in which the image capture completion determiner 386 determines whether or not the image capturing process is completed, by comparing the number of times that radiographic images have been captured in the image capturing conditions with the count from the counter 380. If the count is smaller than the number of times that radiographic images have been captured, then control returns to step S13 shown in FIG. 27, and step S13 and steps subsequent thereto are repeated until the image capturing process is brought to an end. If the image capturing process is completed, control proceeds to step S24, in which the electric power controller 334 is temporarily shut down. More specifically, the image capture completion determiner 386 outputs an image capture completion signal. Based on the image capture completion signal input from the image capture completion determiner 386, the pause processor 340 outputs a pause signal to the electric power controller 334. Based on the pause signal input from the pause processor 340, the electric power controller 334 stops controlling supply of electric power, and waits to be activated at a subsequent time by the electric power supply activator 336. At this stage, the operation sequence of the first radiographic apparatus 10A is brought to an end. If the electric power supply switch is operated again or the electric power supply is turned on again, step S1 shown in FIG. 26 and steps subsequent thereto are repeated.

An operation sequence of the first radiographic apparatus 10A, if the supply timing conditions indicate supply of electric power before capturing of radiographic images, will be described below with reference to the flowcharts shown in FIGS. 28 through 30. Although the electric power manager 390 mainly is involved in the operation sequence to be described below, the cassette selector 364 and the integrated supply 368 may also be included in the operation sequence.

In step S101 shown in FIG. 28, a message is output to the console 1004 and the mobile terminal 42 for prompting the operator 38 to enter image capturing conditions.

In step S102, the electric power supply activator 336 activates the electric power controller 334 based on the present image capturing conditions (order) entered from the console 1004 or the mobile terminal 42. In this case, only the electric power supply activator 336 of a device having an ID, which is the same as the ID of the radiation source device 18 or the cassette 12 used to capture radiation images, which has been registered in advance in the image capturing conditions, activates the corresponding electric power controller 334. The present image capturing conditions may be input from the data center via the network and the mobile terminal 42. The present image capturing conditions are stored in the memory 330.

In step S103, the device connection detector 360 detects whether or not the device, i.e., the radiation source device 18 or the cassette 12, is connected to the first energy input/output unit 300 or the second energy input/output unit 302. After the device connection detector 360 has detected the connection in step S103, control proceeds to step S104, in which the ID acquirer 410 of the electric power manager 390 shown in FIG. 25 acquires the ID of the connected device. More specifically, the ID acquirer 410 sends a transfer request requesting the connected device to transfer the ID thereof. The connected device outputs the ID to the electric power manager 390, and the ID acquirer 410 acquires the ID and stores the ID in the memory 330.

In step S105, the information acquirer 412 for acquiring various information acquires the present image capturing conditions, which already have been stored in the memory 330, a remaining level-of-electric-energy information table corresponding to the ID, previous image capturing conditions corresponding to the ID, and a usage history table corresponding to the ID, and stores such information in the memory 330.

In step S106, the amount-of-consumed-electric-power predictor 414 calculates amounts of electric power to be consumed by the radiation source device 18 and the cassette 12 that is used to capture radiographic images, from conditions concerning the amount of electric power to be supplied (stored in the memory 330), and the present or previous image capturing conditions, which represent the number of radiographic images to be captured, mAs values, etc., from among the battery charging conditions. The amount-of-consumed-electric-power predictor 414 then corrects the calculated amounts of electric power by multiplying the calculated amounts by usage histories of the radiation source device 18 and the cassette 12, i.e., by coefficients corresponding to the number of times that the radiation source device 18 and the cassette 12 have been used, thereby predicting amounts of electric power that are consumed by the radiation source device 18 and the cassette 12 during the present image capturing process, or amounts of electric power consumed by the radiation source device 18 and the cassette 12 during the previous image capturing process. The condition concerning amount of electric power from among the battery charging conditions may be an amount of electric power required to capture radiographic images in the present image capturing process, an amount of electric power required to capture a single radiographic image, or an amount of electric power consumed during the previous image capturing process. If the condition concerning the amount of electric power is an amount of electric power required to capture radiographic images during the present image capturing process, then the amount-of-consumed-electric-power predictor 414 calculates amounts of electric power that are consumed by the radiation source device 18 and the cassette 12 used to capture radiographic images in the present image capturing process, and corrects the calculated amounts of electric power by multiplying the calculated amounts by usage histories of the radiation source device 18 and the cassette 12, i.e., by coefficients corresponding to the number of times that the radiation source device 18 and the cassette 12 have been used, thereby predicting amounts of electric power that are consumed by the radiation source device 18 and the cassette 12 during the present image capturing process, or amounts of electric power consumed by the radiation source device 18 and the cassette 12 during the previous image capturing process. If the condition concerning amount of electric power is an amount of electric power consumed during the previous image capturing process, then the amount-of-consumed-electric-power predictor 414 calculates amounts of electric power consumed by the radiation source device 18 and the cassette 12 in the previous image capturing process, and corrects the calculated amounts of electric power by multiplying the calculated amounts by usage histories of the radiation source device 18 and the cassette 12, i.e., by coefficients corresponding to the number of times that the radiation source device 18 and the cassette 12 have been used, thereby predicting amounts of electric power consumed by the radiation source device 18 and the cassette 12 during the previous image capturing process.

In step S107, the electric power supply route setting unit 370 sets a route for supply of electric power based on the predicted amounts of electric power, and the remaining levels of electric power in the batteries 308 of the radiation source device 18 and the cassette 12 (remaining level-of-electric-energy information tables). Typically, the electric power supply route setting unit 370 sets a route for supply of electric power to a device, the battery of which stores a remaining level of electric power that will be almost eliminated during the present image capturing process. Information concerning the set route is displayed on the display screen of the mobile terminal 42. If the operator 38 intends to supply electric power additionally from other devices, i.e., a radiation source device 18 or a cassette 12 that are not used to capture radiographic images, then the operator 38 enters routes for supplying electric power from such other devices, i.e., routes for supplying electric power from the other devices to the devices having IDs, together with amounts of electric power. If the operator 38 intends to charge a battery as well using another device, i.e., a radiation source device 18 or a cassette 12, then the operator 38 enters a route for supplying electric power to or from the other device, i.e., a route from the other device to the radiation source device 18 or the cassette 12 that is used to capture radiographic images, or a route from the radiation source device 18 or the cassette 12 that is used to capture radiographic images to the other device, together with an amount of electric power to be supplied and the order in which electric power is supplied. Based on the entered route for supplying electric power, the electric power supply route setting unit 370 outputs a supply source instruction signal or a supply destination instruction signal to the electric power supply controller 374 of each of such devices.

In step S108, the amount-of-supplied-electric-power setting unit 372 sets an amount of electric power to be supplied (supplied amount of electric power) based on the predicted amount of electric power and the remaining levels of electric power in the batteries 308 of the radiation source device 18 and the cassette 12 (remaining level-of-electric-energy information tables). Thus, at most, the predicted amount of electric power is supplied to a device, the battery of which stores a remaining level of electric power that will be almost eliminated during the present image capturing process. The amount of electric power, which is supplied to such a device, may be one-half or one-third the predicted amount of electric power. The information of the set amount of electric power is displayed on the display unit 1010 of the console 1004 and a display screen of the mobile terminal 42. The set amount of electric power also can be changed as desired by the console 1004 and the mobile terminal 42. If the operator 38 intends to charge a battery as well, then the amount-of-supplied-electric-power setting unit 372 also sets an amount of electric power to be supplied additionally to charge the battery. The amount of electric power, which is predicted based on the previous image capturing conditions, is supplied in order to supplement the amount of electric power consumed during the previous image capturing process. If the operator 38 intends to charge a battery as well, then the amount-of-supplied-electric-power setting unit 372 also sets an amount of electric power to be supplied additionally to charge the battery. The set amount of electric power is supplied to the electric power supply controller 374 of the corresponding device.

In step S109, if the electric power supply controller 374 is supplied with a supply source instruction signal, then the electric power supply controller 374 controls the battery 308 to output electric power. If the electric power supply controller 374 is supplied with a supply destination instruction signal, then the electric power supply controller 374 controls the battery 308 so as to be supplied with electric power. If supply of electric power to the battery 308 or supply of electric power from the battery 308 is completed, the electric power supply controller 374 outputs a supply termination signal.

In step S110, the information updater 416 of the electric power manager 390, in the remaining level-of-electric-energy information table, subtracts the amount of supplied electric power from the remaining level of electric power of the device that serves as the electric power supply source, and adds the amount of supplied electric power to the remaining level of electric power of the device that serves as the electric power supply destination.

In step S111, the electric power supply completion output unit 388 outputs an electric power supply completion signal based on supply termination signals input from the electric power supply controllers 374 of all of the devices to which electric power has been supplied.

In step S112, the image capture permission instructing unit 384 outputs a message, which represents permission to capture an image, to the mobile terminal 42 based on the electric power supply completion signal input from the electric power supply completion output unit 388.

In step S113 shown in FIG. 29, the operator 38 prepares the first radiographic apparatus 10A for capturing radiographic images, at a site to which the first radiographic apparatus 10A has been carried. This preparatory procedure has already been described in detail above, and will not be described below.

In step S114, the operator 38 turns on the exposure switch 48 in order to start capturing radiographic images of the subject 50. In this case, the counter 380 updates the count thereof by incrementing the count by +1.

When the operator 38 turns on the exposure switch 48 in step S114, the electric power supply limiter 338 outputs a supply limit signal to the electric power controller 334, during the period referred to above in step S115. During the period in which the electric power controller 334 is supplied with the supply limit signal, the electric power supply operation of the electric power controller 334 is limited.

In step S116, the remaining level prediction updater 392 updates, by way of subtraction, the remaining levels of electric power stored in the batteries, which are recorded in the remaining level-of-electric-energy information tables, i.e., the remaining levels of electric power stored in the batteries 308 of the radiation source device 18 and the cassette 12, which are utilized for capturing radiographic images. More specifically, with respect to the radiation source device 18 and the cassette 12 that carry out capturing of radiographic images, the remaining level prediction updater 392 calculates the amounts of electric power consumed during each time the exposure switch 48 is turned on, based on the image capturing conditions and the usage history tables, and subtracts the calculated amounts of electric power from the remaining levels of electric power stored in the batteries 308 of the radiation source device 18 and the cassette 12, which are recorded in the remaining level-of-electric-energy information tables.

In step S117, the electric power controller 334 determines whether or not electric power needs to be re-supplied, based on whether the electric power supply controller 374 of any device has output an imaging disabled signal.

If the electric power controller 334 judges that electric power needs to be re-supplied, then control proceeds to step S118, in which the image capture interruption instructing unit 378 outputs a message indicative of an image capture interruption to the console 1004 and the mobile terminal 42. The console 1004 and the mobile terminal 42 displays the message on the display unit 1010 and a display screen thereof, respectively, and preferably output an alarm sound, for prompting the operator 38 to interrupt the image capturing process.

Thereafter, in step S119, the re-supply instructing unit 382 outputs a re-supply instruction signal to the electric power supply route setting unit 370, the amount-of-supplied-electric-power setting unit 372, and the electric power manager 390.

In step S120, the electric power supply route setting unit 370 sets, as a re-supply route, a route for supplying electric power to the device having the ID included in the input re-supply instruction signal, and outputs a supply source instruction signal or a supply destination instruction signal to the electric power supply controller 374 of each device, based on the set re-supply route.

In step S121, the amount-of-consumed-electric-power predictor 414 calculates amounts of electric power to be consumed by the device having the aforementioned ID, i.e., the radiation source device 18 or the cassette 12 that is re-supplied with electric power, from among the image capturing conditions for an image capturing process to be carried out, and from which image capturing conditions for radiographic images already captured (indicated by the count) are excluded, among the battery charging conditions stored in the memory 330 and the present image capturing conditions representative of the number of radiographic images to be captured, mAs values, etc. The amount-of-consumed-electric-power predictor 414 also corrects the calculated amounts of electric power by multiplying the calculated amounts by the usage history of the device having the ID, i.e., a coefficient corresponding to the number of times that the device of the ID has been used, thereby predicting an amount of electric power that will be consumed by the device of the ID in the image capturing process to be carried out.

In step S122, the amount-of-supplied-electric-power setting unit 372 sets the amount of electric power predicted by the amount-of-consumed-electric-power predictor 414, as an amount of re-supplied electric power, and supplies information concerning the set amount of re-supplied electric power to the electric power supply controller 374 of the corresponding device.

In step S123, if the electric power supply controller 374 is supplied with a supply source instruction signal, then the electric power supply controller 374 controls the battery 308 to output electric power. If the electric power supply controller 374 is supplied with a supply destination instruction signal, then the electric power supply controller 374 controls the battery 308 so as to be supplied with electric power. If supply of electric power to the battery 308 or supply of electric power from the battery 308 is completed, the electric power supply controller 374 outputs a supply termination signal.

In step S124, the electric power supply completion output unit 388 outputs an electric power supply completion signal, based on supply termination signals input from the electric power supply controllers 374 of all of the devices to which electric power has been re-supplied.

In step S125, the image capture permission instructing unit 384 outputs a message to the console 1004 and the mobile terminal 42 representing permission to capture images, based on the electric power supply completion signal input from the electric power supply completion output unit 388. Thereafter, control returns to step S114 and steps subsequent thereto.

If the electric power controller 334 judges that no electric power needs to be re-supplied in step S117, then control proceeds to step S126 shown in FIG. 30, in which the image capture completion determiner 386 determines whether or not the image capturing process is completed by comparing the number of times that radiographic images have been captured in the image capturing conditions with the count of the counter 380. If the count is smaller than the number of times that radiographic images have been captured, then control returns to step S114 shown in FIG. 29, and step S114 and steps subsequent thereto are repeated until the image capturing process is brought to an end. If the image capturing process is completed, control proceeds to step S127 shown in FIG. 30, in which the usage history updater 394 adds the number of times that the exposure switch 48 has been turned on to the number of times recorded in the usage history table, i.e., the number of times that the radiation source device 18 and the cassette 12 have been used to capture radiographic images.

In step S128, the remaining level information transfer unit 396 transfers the remaining level information table via the network to the database of the data center for updating.

In step S129, the usage history transfer unit 398 transfers the usage history table via the network to the database of the data center for updating.

In step S130, the electric power controller 334 is temporarily shut down. More specifically, the image capture completion determiner 386 outputs an image capture completion signal. Based on the image capture completion signal input from the image capture completion determiner 386, the pause processor 340 outputs a pause signal to the electric power controller 334. Based on the pause signal input from the pause processor 340, the electric power controller 334 stops controlling supply of electric power, and waits to be activated at a subsequent time by the electric power supply activator 336. At this stage, the operation sequence of the first radiographic apparatus 10A is brought to an end. If the image capturing conditions are entered again, then step S102 shown in FIG. 28 and steps subsequent thereto are repeated.

An operation sequence of the first radiographic apparatus 10A, if the supply timing conditions indicate supply of electric power after capturing of radiographic images, will be described below with reference to the flowcharts shown in FIGS. 31 and 32. Although the electric power manager 390 mainly is involved in the operation sequence to be described below, the cassette selector 364 and the integrated supply 368 may also be included in the operation sequence.

In step S201 shown in FIG. 31, a message is output to the console 1004 and the mobile terminal 42, for prompting the operator 38 to enter image capturing conditions.

In step S202, the operator 38 prepares the first radiographic apparatus 10A for capturing radiographic images at a site where the first radiographic apparatus 10A has been carried. In step S203, the operator 38 turns on the exposure switch 48 to start capturing radiographic images of the subject 50.

In step S204, the electric power controller 334 determines whether or not electric power needs to be re-supplied, based on whether the electric power supply controller 374 of any given device has output an imaging disabled signal.

If the electric power controller 334 judges that electric power needs to be re-supplied, then control proceeds to step S205, in which the image capture interruption instructing unit 378 outputs a message indicating interruption of image capturing to the console 1004 and the mobile terminal 42. Thereafter, in step S206, the re-supply instructing unit 382 outputs a re-supply instruction signal to the electric power supply route setting unit 370, the amount-of-supplied-electric-power setting unit 372, and the electric power manager 390, thereby activating the electric power supply route setting unit 370, the amount-of-supplied-electric-power setting unit 372, and the electric power manager 390 in an interrupt routine.

In step S207, the electric power supply route setting unit 370 sets a route for supplying electric power to the device having the ID included in the input re-supply instruction signal, as a re-supply route, and based on the set re-supply route, outputs a supply source instruction signal or a supply destination instruction signal to the electric power supply controller 374 of each device.

In step S208, the amount-of-consumed-electric-power predictor 414 calculates amounts of electric power that are consumed by the device having the ID, i.e., the radiation source device 18 or the cassette 12 that are re-supplied with electric power, from image capturing conditions for an image capturing process to be carried out, from which image capturing conditions for radiographic images already captured (indicated by the count) are excluded, from among the battery charging conditions stored in the memory 330, and the present image capturing conditions representative of the number of radiographic images to be captured, mAs values, etc. The amount-of-consumed-electric-power predictor 414 also corrects the calculated amounts of electric power by multiplying the calculated amounts by a usage history of the device of the ID, i.e., a coefficient corresponding to the number of times that the device of the ID has been used, thereby predicting an amount of electric power to be consumed by the device of the ID in the image capturing process to be carried out.

In step S209, the amount-of-supplied-electric-power setting unit 372 sets the amount of electric power predicted by the amount-of-consumed-electric-power predictor 414 as an amount of re-supplied electric power, and outputs the information concerning the set amount of re-supplied electric power to the electric power supply controller 374 of the corresponding device.

In step S210, if the electric power supply controller 374 is supplied with a supply source instruction signal, then the electric power supply controller 374 controls the battery 308 to output electric power. Further, if the electric power supply controller 374 is supplied with a supply destination instruction signal, then the electric power supply controller 374 controls the battery 308 so as to be supplied with electric power. If supply of electric power to the battery 308 or supply of electric power from the battery 308 is completed, then the electric power supply controller 374 outputs a supply termination signal.

In step S211, the electric power supply completion output unit 388 outputs an electric power supply completion signal based on supply termination signals, which are input from the electric power supply controllers 374 of all of the devices to which electric power has been re-supplied.

In step S212, the image capture permission instructing unit 384 outputs a message representing permission to capture an image to the console 1004 and the mobile terminal 42, based on the electric power supply completion signal input from the electric power supply completion output unit 388. Thereafter, control returns to step S203 and steps subsequent thereto.

If the electric power controller 334 judges that no electric power needs to be re-supplied in step S204, then control proceeds to step S213, in which the image capture completion determiner 386 determines whether or not the image capturing process is completed. If the image capturing process is not completed, then control returns to step S203, and step S203 and steps subsequent thereto are repeated until the image capturing process is brought to an end. If the image capturing process has finished, control proceeds to step S214, in which the electric power supply activator 336 activates the electric power controller 334 based on an image capture completion signal input from the image capture completion determiner 386. In this case, only the electric power supply activator 336 of a device having an ID that is the same as the ID of the radiation source device 18 or the cassette 12 that is used to capture radiation images, which has been registered in advance in the image capturing conditions, activates the corresponding electric power controller 334.

In step S215 shown in FIG. 32, the device connection detector 360 detects whether or not the device is connected to the first energy input/output unit 300 or the second energy input/output unit 302.

After the device connection detector 360 has detected the connection in step S215, control proceeds to step S216, in which the ID acquirer 410 of the electric power manager 390 acquires the ID of the connected device. Thereafter, in step S217, the information acquirer 412 for acquiring various information acquires the present image capturing conditions, which have already been stored in the memory 330, a remaining level-of-electric-energy information table corresponding to the ID, previous image capturing conditions corresponding to the ID, and a usage history table corresponding to the ID, and stores such information in the memory 330.

In step S218, the amount-of-consumed-electric-power predictor 414 calculates amounts of electric power to be consumed by the radiation source device 18 and the cassette 12, which are used to capture radiographic images, from a condition concerning the amount of electric power to be supplied, and the present or previous image capturing conditions representative of the number of radiographic images to be captured, mAs values, etc., from among the battery charging conditions.

In step S219, the electric power supply route setting unit 370 sets a route for supply of electric power, based on the predicted amounts of electric power and the remaining levels of electric power in the batteries 308 of the radiation source device 18 and the cassette 12 (remaining level-of-electric-energy information tables).

Thereafter, in step S220, the amount-of-supplied-electric-power setting unit 372 sets an amount of electric power to be supplied (supplied amount of electric power), based on the predicted amount of electric power, and the remaining levels of electric power in the batteries 308 of the radiation source device 18 and the cassette 12 (remaining level-of-electric-energy information tables).

In step S221, if the electric power supply controller 374 is supplied with a supply source instruction signal, then the electric power supply controller 374 controls the battery 308 to output electric power. Further, if the electric power supply controller 374 is supplied with a supply destination instruction signal, then the electric power supply controller 374 controls the battery 308 so as to be supplied with electric power. In a case where supply of electric power to the battery 308 or supply of electric power from the battery 308 is completed, the electric power supply controller 374 outputs a supply termination signal.

In step S222, the information updater 416, in the remaining level-of-electric-energy information table, subtracts the amount of supplied electric power from the remaining level of electric power of the device that serves as an electric power supply source, and adds the amount of supplied electric power to the remaining level of electric power of the device that serves as an electric power supply destination.

In step S223, the electric power supply completion output unit 388 outputs an electric power supply completion signal, based on supply termination signals input from the electric power supply controllers 374 of all of the devices to which electric power has been supplied.

In step S224, the usage history updater 394 adds the number of times that the exposure switch 48 has been turned on to the number of times recorded in the usage history table, i.e., the number of times that the radiation source device 18 and the cassette 12 have been used to capture radiographic images.

In step S225, the remaining level information transfer unit 396 transfers the remaining level information table via the network to the database of the data center for updating. In step S226, the usage history transfer unit 398 transfers the usage history table via the network to the database of the data center for updating. Thereafter, in step S227, the pause processor 340 temporarily shuts down the electric power controller 334. At this stage, the operation sequence of the first radiographic apparatus 10A is brought to an end. If the image capturing conditions are entered again, step S202 shown in FIG. 31 and steps subsequent thereto are repeated.

For a method of supplying electric power using the console 1004, electric power may be supplied according to a process that differs from the process carried out by the above-mentioned process. For example, the different process comprises an electric power collecting process for collecting all or part of the electric power stored in the battery 308 of the radiation source device 18, and all or part of the electric power stored in the battery 308 of the cassette 12, for the battery unit 304 of the console 1004.

An electric power collector 420 for carrying out the above electric power collecting process will be described below with reference to FIGS. 33 and 34.

The electric power collector 420 is incorporated in the battery controller 306. The electric power collector 420 is activated by an operation made by the operator 38 in order to instruct collection of electric power, e.g., by left-clicking on an icon representing collection of electric power shown on the display unit 1010 of the console 1004. As shown in FIG. 33, the electric power collector 420 comprises the device connection detector 360, an electric power collection ID acquirer 422, an electric power collection information acquirer 424, an electric power collection supply route setting unit 426, an electric power collection level setting unit 428, the electric power supply controller 374, the remaining level detector 376, an electric power collection remaining level updater 430, and an electric power collection remaining level information transfer unit 432.

Details of an operation sequence of the electric power collector 420 will be described below with reference to FIGS. 33 and 34.

In step S301 shown in FIG. 34, the device connection detector 360 detects devices, i.e., the radiation source device 18 and the cassette 12, which are connected to the first energy input/output unit 300 and the second energy input/output unit 302.

The electric power collection ID acquirer 422 sends a transfer request to the connected devices for transferring IDs. Based on the transfer request, the connected devices output IDs thereof to the electric power collector 420. The electric power collection ID acquirer 422 acquires the IDs from the connected devices, and registers the IDs in the memory 330 (see FIG. 20) in step S302.

The electric power collection information acquirer 424 acquires remaining level information tables corresponding to the IDs, and stores the acquired remaining level information tables in the memory 330 in step S303.

The electric power collection supply route setting unit 426 sets a supply route from the device connected to the first energy input/output unit 300 to the console 1004, and a supply route from the device connected to the second energy input/output unit 302 to the console 1004. Based on the set supply routes, in step S304, the electric power collection supply route setting unit 426 outputs supply source instruction signals to the electric power supply controllers 374 of the respective devices.

In step S305, the electric power collection level setting unit 428 sets an electric power collection level using the operating unit 1008, e.g., a keyboard or a mouse, of the console 1004. The electric power collection level represents the sum of a first electric power level to be supplied from the device connected to the first energy input/output unit 300 of the console 1004 to the battery 308 of the console 1004, and a second electric power level to be supplied from the device connected to the second energy input/output unit 302 of the console 1004 to the battery 308 of the console 1004. The first electric power level and the second electric power level are supplied respectively to the electric power supply controllers 374 of the respective devices.

Based on the supply source instruction signals, the electric power supply controllers 374 of the devices control the batteries 308 thereof to output electric power. Further, based on a supply source instruction signal, the electric power supply controller 374 of the console 1004 controls the battery 308 thereof to input electric power in step S306. The electric power supply controllers 374 control the batteries 308 to supply electric power, and to be supplied with electric power, at a constant charging rate or at a discharging rate based on the remaining level sent from the remaining level detector 376. If the level of electric power to be supplied is low, then it is possible to charge and discharge the batteries 308 quickly.

In step S307, the electric power collection remaining level updater 430 updates the remaining battery level corresponding to the ID of the device that is connected to the first energy input/output unit 300, by subtracting the first electric power level from the remaining battery level. The electric power collection remaining level updater 430 also updates the remaining battery level corresponding to the ID of the device that is connected to the second energy input/output unit 302, by subtracting the second electric power level from the remaining battery level.

In a case where the updating process of the electric power collection remaining level updater 430 is completed, then in step S308, the electric power collection remaining level information transfer unit 432 transfers the remaining level information tables via the network to the database of the data center for updating.

The electric power collector 420 may be activated by operations made by the operator 38 on the operating unit 1008, for example, regardless of location and time. For example, in a case where the first mobile apparatus 1000A is carried into a data center, the electric power collector 420 may be activated in order to collect electric power in the battery 308 of the console 1004. Then, in a case where the first mobile apparatus 1000A is carried to a site, the radiation source device 18 and the cassette 12, which are used to capture radiographic images, may be supplied with electric power from the console 1004. In this case, the electric power manager 390 supplies an optimum electric power level for capturing radiographic images to the radiation source device 18 and to the cassette 12. Alternatively, the electric power collector 420 may be activated at a site, so as to collect into the console 1004 electric power from a radiation source device 18 and a cassette 12, which have deteriorated significantly and which cannot be used to capture radiographic images, and to supply the collected electric power to the radiation source device 18 and the cassette 12 that currently are being used to capture radiographic images.

If the console 1004 is used, an electric power supply status (the remaining battery level) to the respective radiation source devices 18, and to the respective cassettes 12 in one or more first radiographic apparatus 10A may be displayed on the display unit 1010 of the console 1004 as a guidance (mentioned as “guidance display”). Confirming the remaining battery level through the guidance display, the operator 38 can easily determine which first radiographic apparatus 10A should be used, or which combination of the radiation source device 18 and the cassette 12 should be used. If such a guidance display as mentioned is used, the remaining level information from the respective remaining level detectors 376 or from the remaining level information table may be used.

Since the first mobile apparatus 1000A limits a route for supply of electric power, e.g., only the route from the radiation source device 18 to the cassette 12, or only the route from the cassette 12 to the radiation source device 18. Thus, electric power does not have to be supplied in vain and the first mobile apparatus 1000A can reduce consumption of electric power.

A battery is required for only the battery 308 of the radiation source device 18 or only the battery 308 of the cassette 12. For example, if the electric power controller 334 controls electric power supplied only along a route from the radiation source device 18 to the cassette 12, then a built-in capacitor may be used as the battery 308 of the cassette 12. In such a case, a separate battery is not required as the battery 308 for the cassette 12. Similarly, if the electric power controller 334 controls electric power so as to be supplied with power only along a route from the cassette 12 to the radiation source device 18, then a built-in capacitor may be used as the battery 308 of the radiation source device 18. In such a case, a separate battery is not required as the battery 308 for the radiation source device 18.

Further, it is also possible to distinguish functions of a first radiographic apparatus 10A having a built-in capacitor as the battery 308 from those of a first radiographic apparatus 10A having a secondary battery as the battery 308. A secondary battery utilizes chemical reactions on positive and negative terminals, and can charge and discharge. Though the capacity of a secondary battery is large, it cannot be charged quickly. On the other hand, a capacitor can be charged quickly though the capacity thereof is not so large since electric charge is stored using electrostatic force. Therefore, if the number of radiographic images to be captured is large, then the first radiographic apparatus 10A having a secondary battery may be used. If a single radiographic image is desired to be captured quickly, then the first radiographic apparatus 10A having a built-in capacitor may be used. In this case, the aforementioned guidance display can be used. That is, through the guidance display, an electric power supply status (the remaining battery level) in one or more first radiographic apparatus 10A may be displayed, e.g., on the display unit 1010 of the console 1004 as a guidance. If each type of the batteries 308 of the one or more first radiographic apparatus 10A is also displayed in the guidance display, it will be possible to easily select the most suitable first radiographic apparatus 10A that satisfies the present image capturing conditions (such as the need for the large number of radiographic images to be captured, or the need for quick radiographic image capturing of a single image), based on the electric power supply status of each of the first radiographic apparatus 10A and each type of the batteries 308.

If the cart unit 1002 is moved by electric power, it is only necessary to prepare a battery for supplying electric power to an electromotive drive system of the cart unit 1002. In this case, it is not necessary to supply electric power to the first radiographic apparatus 10A or other devices, but it is sufficient to secure electric power only for the movement of the cart unit 1002. Thus, it is not necessary to use conventional dedicated batteries (lead battery or the like), but it is sufficient to use a small lithium battery or the like.

Thus, even if the cart unit 1002 is moved by electric power, the weight of the first mobile apparatus 1000A can be reduced and the first mobile apparatus 1000A is used easily. The battery thereof can be replaced at any place such as a medical site, which can lead to elimination of the need of charging facilities for a mobile radiographic image capturing apparatus. Then, it becomes unnecessary for the first mobile apparatus 1000A to secure electric power to return to the charging facilities, and the electric power can be sufficiently used for capturing radiographic images. Also, the first mobile apparatus 1000A can quickly attend to unexpected recapturing or additional capturing of radiographic images. Since the battery can be replaced easily, the first mobile apparatus 1000A can be carried to one or more homes in one region for capturing radiographic images of patients receiving home-care services.

In a case where a need arises to capture radiographic images of examinees at accident sites, disaster sites, or on transport vehicles such as ambulances (while in movement or at rest), railway cars, ships, aircrafts, or the like, the first mobile apparatus 1000A can be moved to an examinee, such as an accident victim or a disaster victim, and can used quickly to start capturing radiographic images of the examinee, without requiring the examinee to be moved unduly to a hospital or the like. While on a transport vehicle, the first mobile apparatus 1000A can quickly begin capturing radiographic images of the examinee, without having to wait for the transport vehicle to arrive at a station, a port, or an airport. While on an ambulance, the first mobile apparatus 1000A can send captured radiographic image information to a data center before the ambulance reaches the hospital. As a consequence, a doctor at the hospital can recognize the condition of the examinee in advance, and hence can quickly prepare the examinee for treatment.

It is possible to carry one or more first mobile apparatus 1000A on a vehicle or the like to perform periodic or temporary medical checkups at schools or large corporations where the number of examinees is large. Usually, since a single mobile medical checkup motor vehicle (of large type), which is equipped with a single ordinary radiographic image capturing apparatus, is dispatched to such locations, it has been customary for such examinees to have to wait a very long time before radiographic images of the examinees can be captured. According to the present invention, one or more first mobile apparatus 1000A housing several first radiographic apparatus 10A can be used simultaneously in order to minimize the waiting time before radiographic images of examinees can be captured.

Electric power can be supplied along a wired route or a wireless route. For example, electric power can be supplied along a route from a radiation source device 18 used in an image capturing process to a cassette 12 used in the image capturing process, along a route from another radiation source device 18, which is not used in an image capturing process, to the cassette 12 that is used in the image capturing process, or along a route from another cassette 12, which is not used in an image capturing process, to the cassette 12 that is used in the image capturing process. In addition, electric power can be supplied along a route from a cassette 12 used in an image capturing process to a radiation source device 18 used in the image capturing process, or along a route from another radiation source device 18, which is not used in an image capturing process, to the radiation source device 18 that is used in the image capturing process. Electric power can be supplied to a device, e.g., the radiation source device 18 or the cassette 12, in a wireless fashion, when the device enters into an area enabling wireless supply of electric power thereto.

If an electric power supply route is fixed to a route from the radiation source device 18 to the cassette 12, or from the cassette 12 to the radiation source device 18, then since a user is required to confirm only the level of electric power in the supply source, a preparatory process for supplying electric power can be simplified, and radiographic images can be captured quickly.

If the first energy input/output unit 300 is used via a wired connection and the second energy input/output unit 302 is used via a wireless connection, then composite connections are made available for supplying electric power. For example, electric power can be supplied along a route from the radiation source device 18 to the cassette 12 and another radiation source device 18, along a route from the radiation source device 18 to the cassette 12 and another cassette 12, along a route from the cassette 12 to the radiation source device 18 and another cassette 12, or along a route from the cassette 12 to the radiation source device 18 and another radiation source device 18.

The radiation source device 18 is supplied with electric power preferentially from a cassette 12 that has been deteriorated greatly, or from a cassette 12 having a small remaining built-in memory capacity. Therefore, electric power stored in a cassette 12, which has not been deteriorated greatly, or in a cassette 12 having a large remaining built-in memory capacity, can be saved, thereby enabling the first mobile apparatus 1000A to be readily available for emergencies.

Similarly, the radiation source device 18 is supplied with electric power preferentially from a cassette 12 that is located closer to the radiation source device 18. Therefore, the time required to supply electric power to the radiation source device 18 is shortened, thereby making the first mobile apparatus 1000A readily available for emergencies.

Similarly, the radiation source device 18 is supplied with electric power preferentially from a cassette 12 that is smaller in size. Therefore, electric power stored in a cassette 12, which is larger in size and hence more versatile, can be saved, thereby making the first mobile apparatus 1000A readily available for emergencies.

Since the first mobile apparatus 1000A includes the electric power manager 390, the level of electric power required to capture a desired number of radiographic images is managed, and the remaining levels of the batteries 308 in the devices are controlled for flexible electric power supply. Thus, it is possible to supply electric power from a device, the battery of which stores excessive electric power to a device having a battery with insufficient electric power, for example, up to the level of the required electric power. Also, since electric power required to capture radiographic images can flexibly be supplied from another device, which is not used in the image capturing process, to a device which is used in the image capturing process having a battery with insufficient electric power, for example, up to the level of the required electric power. As a result, the radiation source device 18 and the cassette 12 can be supplied efficiently with electric power, thereby making the first mobile apparatus 1000A readily available in an emergency, and reducing the electric power consumption. Since electric power can be managed automatically, troublesome procedures such as checking batteries can be omitted, and image capturing process can be performed quickly. Further, since the electric power manager 390 is included, the printers 170 a, 170 b, 170 c having large electric power consumption may be installed in the radiation source device 18 and the cassette 12 of the first radiographic apparatus 10A, and in the first mobile apparatus 1000A.

The timing at which electric power is supplied can be determined as desired. For example, the timing at which electric power is supplied can be determined in order to supply electric energy before an image capturing process is carried out. In this manner, electric power required to capture radiographic images can be ensured without wasteful electric power consumption. Since electric power required to capture radiographic images is predicted and supplied in accordance therewith, electric power is supplied efficiently. If the timing at which electric power is supplied is determined in order to supply electric energy after an image capturing process has been performed, then since the amount of electric power required to capture at least one radiographic image is ensured, the first mobile apparatus 1000A can quickly be readied to perform a next image capturing process.

Supply of electric power is stopped during a period in which noise is likely to be added to radiographic image information being captured. Consequently, wasteful consumption of electric power is minimized for enabling low electric power consumption, while at the same time the quality of the radiographic image information is prevented from becoming degraded.

In the above embodiment, the battery controller 306 is provided in each of the devices. However, among the components that make up the battery controller 306, the electric power supply controller 374 and the remaining level detector 376 may be provided in each of the devices, whereas the other components thereof may be provided only in one of a radiation source device 18, a cassette 12, and a console 1004, which are used in an image capturing process. Among the components of the electric power controller 334, only the electric power manager 390 may be provided in one of the radiation source device 18, the cassette 12, and the console 1004, which are used in an image capturing process.

In a case where the first mobile apparatus 1000A is moved, the radiation source device 18 and the cassette 12 of the first radiographic apparatus 10A are housed in the slot 1036 of the first mobile apparatus 1000A, in the state in which the radiation source device 18 and the cassette 12 are integrally joined to each other by the joining mechanism 82. Thus, the radiation source device 18 and the cassette 12 are prevented from falling down even in a case where the first mobile apparatus 1000A moves. Further, since it is unnecessary to hold the radiation source device 18 and the like by hand while the first mobile apparatus 1000A is moving, the first mobile apparatus 1000A can be moved easily and smoothly.

For capturing radiographic images, the first radiographic apparatus 10A is taken out from the slot 1036 of the first mobile apparatus 1000A. After the radiation source device 18 and the cassette 12 are separated from each other, the radiation source device 18 may be attached to the distal end 1006 a of the arm unit 1006, and the cassette 12 may be disposed in confronting relation to the radiation source device 18. Thus, the first mobile apparatus 1000A can simply and quickly be readied for capturing radiographic images.

Since the console 1004 can supply electric power to respective devices, it is possible to set a supply route from the console 1004 to a radiation source device 18 that is used to capture radiographic images, as well as a supply route from the console 1004 to a cassette 12 that is used to capture radiographic images. It also is possible to set a supply route from the console 1004 as a supply source to the aforesaid radiation source device 18, as well as a supply route from the console 1004 as a supply source to the aforesaid cassette 12. Furthermore, it is possible to set a supply route from the aforesaid radiation source device 18 via the console 1004 to the aforesaid cassette 12, as well as a supply route from the aforesaid cassette 12 via the console 1004 to the aforesaid radiation source device 18.

Since electric power can be supplied from the console 1004 to the radiation source device 18 and the cassette 12, or electric power can be supplied between the radiation source device 18 and the cassette 12 via the console 1004, the console 1004 can perform a centralized electric power management process for efficiently supplying electric power between the radiation source device 18 and the cassette 12. Inasmuch as electric power can be collected from one or more radiation source devices 18 and one or more cassettes 12 into the console 1004, the console 1004 can perform a battery function that enables efficient electric power management, so as to avoid power supply problems such as sudden power supply interruptions in a case where electric power needs to be supplied to the radiation source device 18 and the cassette 12.

In the first mobile apparatus 1000A, the first radiographic apparatus 10A may comprise a water-resistant, hermetically sealed structure, thereby making the entire first radiographic apparatus 10A resistant to contamination by blood and bacteria. If necessary, the first radiographic apparatus 10A may be cleaned and sterilized for enabling repetitive use.

The first radiographic apparatus 10A may perform wireless communications with an external device by way of ordinary wireless communications using radio waves, or by way of optical wireless communications using infrared rays or the like.

In the first embodiment, as shown in FIG. 35, the first radiographic apparatus 10A may be devoid of the tape measure 72. Without the tape measure 72, the first radiographic apparatus 10A provides the same advantages offered by components thereof other than the tape measure 72.

As described above, major components of the joining mechanism 82 are provided in the cassette 12. However, the joining mechanism 82 may be provided in the radiation source device 18. Such a modification offers the same advantages as those referred to above.

The first radiographic apparatus 10A may be modified as described below.

FIG. 36 shows a first radiographic apparatus 10A according to a modification, in which the unlocking button 34, the hook 64, etc., are provided in the radiation source device 18.

As shown in FIG. 36, the side 14 a of the cassette 12 does not include the aforementioned holders 16 a, 16 b, and the radiation source device 18 has a flat side, which faces the side 14 a of the cassette 12. Opposite ends of the radiation source device 18 have respective unlocking buttons 34. The radiation source device 18 also has through holes 62 and hooks 64 provided in the flat side thereof, which faces the side 14 a of the cassette 12, near opposite ends of the radiation source device 18. Connection terminals 68 a, 68 b are disposed on the flat side of the radiation source device 18 near one of the ends of the radiation source device 18.

The side 14 a of the cassette 12 has through holes 66 defined therein, which are in alignment with the respective through holes 62 and connection terminals 70 a, 70 b, which in turn are in alignment with the connection terminals 68 a, 68 b.

The first radiographic apparatus 10A shown in FIG. 36 operates in the following manner. While the flat side of the radiation source device 18 and the side 14 a of the cassette 12 face toward each other, the hooks 64 are inserted into the respective through holes 66, and the connection terminals 68 a, 68 b and the connection terminals 70 a, 70 b are brought into engagement with each other. In this case, the radiation source device 18 and the cassette 12 are integrally joined to each other.

The first radiographic apparatus 10A shown in FIG. 36 offers the same advantages as the first radiographic apparatus 10A according to the first embodiment.

According to the modification shown in FIG. 36, since the unlocking buttons 34 are disposed on opposite ends of the radiation source device 18, an operator 38 can easily disconnect the radiation source device 18 from the cassette 12, simply by detaching the radiation source device 18 from the cassette 12 while pressing the unlocking buttons 34.

In the first embodiment, as shown in FIG. 37, a cradle 220 for charging the batteries 308 of the first radiographic apparatus 10A may be positioned at a desired location in the hospital, for example. The cradle 220 is not only capable of charging the batteries 308, but may also have a wireless or wired communication function for sending and receiving necessary information to and from an external device in the hospital, for example. Information sent from the cradle 220 may include radiation image information recorded in the first radiographic apparatus 10A, which is connected to the cradle 220.

The cradle 220 has a display unit 222 for displaying the charged state of the first radiographic apparatus 10A, which is connected to the cradle 220, and other necessary information, including radiation image information acquired from the first radiographic apparatus 10A.

A plurality of cradles 220 may be connected through a network, and charged states of respective first radiographic apparatus 10A, which are connected to the cradles 220, may be retrieved through the network, so that the user can confirm the locations of first radiographic apparatus 10A that are sufficiently charged, based on the retrieved charged states.

A mobile radiographic image capturing apparatus according to a second embodiment of the present invention, which will hereinafter be referred to as a “second mobile apparatus 1000B”, will be described below with reference to FIGS. 38 through 46.

The second mobile apparatus 1000B essentially is identical in structure to the first mobile apparatus 1000A according to the first embodiment, as shown in FIG. 38, but differs therefrom in that one or more mobile second radiographic apparatus 10B, which will be described later, are accommodated in a cart unit 1002.

As shown in FIG. 39, the second radiographic apparatus 10B essentially is identical in structure to the first radiographic apparatus 10A according to the first embodiment, but differs therefrom in that a detecting screen 250 is drawn out slightly from the cassette 12 through the side 14 b thereof that is remote from the side 14 a on which the holders 16 a, 16 b project, and a weight bar 252 is coupled to a distal end of the detecting screen 250. Among the other sides 14 c, 14 d of the cassette 12, side 14 c has the first energy input/output unit 300 or the second energy input/output unit 302 (see FIG. 19) for inputting and outputting electric power through a wired or wireless link, for example, a USB terminal 28 that serves as an interface means for sending and receiving information to and from an external device, a card slot 32 for inserting the memory card 30 therein, and the unlocking button 34, to be described later. On an upper surface 254 of the cassette 12, the mobile terminal 42 is mounted, which is detachable from the cassette 12 and includes the display unit 36 and the operating unit 40, which is operated by the operator 38. The radiation source device 18 has an exposure switch 48 (see FIG. 13), which can be operated by the operator 38 in order to cause the radiation source 44, which shall be descried later, to start emitting radiation 46.

The second mobile apparatus 1000B is also carried (moved) to an accident or disaster site, as well as a patient room in the hospital or a home of a person receiving home-care services. Thus, in the cassette 12 and the radiation source device 18 of the second radiographic apparatus 10B, at least a portion surrounding an electric system thereof is often sealed. Therefore, contactless electric power supply through wireless connections or the like is desirable for an electric power supply method, compared to contact electric power supply by wired connections or the like.

FIGS. 39 and 40 show the second radiographic apparatus 10B in a state in which the operator 38 has taken out the second radiographic apparatus 10B from the slot 1036 of the cart unit 1002. In this state, the radiation source device 18 and the cassette 12 are joined integrally to each other.

The mobile second radiographic apparatus 10B will be explained in detail with reference to FIGS. 39 through 46.

As shown in FIG. 45, the upper surface 254 of the cassette 12 has the recess 54, which accommodates the mobile terminal 42 therein. As shown in FIGS. 41 and 42, the cassette 12 houses therein a storage box 256, accommodating therein a roll screen, which constitutes a rolled form of the detecting screen 250 and is made of a flexible material permeable to radiation 46. The storage box 256 supports on a side thereof a rotary encoder 258 for detecting the length by which the detecting screen 250 has been reeled out from the storage box 256. The side wall 52 b of the cassette 12, which makes up the side 14 b, has a slot 260 defined therein, through which the detecting screen 250 can be reeled out from the storage box 256.

In a case where the operator 38 pulls the weight bar 252 in a direction away from the cassette 12, the detecting screen 250 is drawn or extended out from the storage box 256 through the slot 260. In a case where the second radiographic apparatus 10B is being carried, the detecting screen 250 is rolled up inside the storage box 256. In a case where the second radiographic apparatus 10B is operated to capture radiographic images, as shown in FIGS. 44, 45 and 46, the detecting screen 250 is drawn out or extended substantially flatwise underneath the radiation source device 18 by the operator 38 pulling the weight bar 252. The detecting screen 250 has gradations 262 on both side edges thereof along the direction in which the detecting screen 250 is pulled.

As shown in FIG. 44, the detecting screen 250 houses therein a grid 84 for removing scattered rays of radiation 46 from the subject 50 in a case where the radiation source 44 applies radiation 46 to the subject 50, a radiation detector 86 for detecting radiation 46 that has passed through the subject 50, and a lead sheet 89 for absorbing back scattered rays of radiation 46, which are successively arranged in this order from the irradiated surface 20 of the detecting screen 250, i.e., the upper surface of the detecting screen 250, as shown in FIGS. 43 through 46. The irradiated surface 20 may be constructed as the grid 84. The grid 84, the radiation detector 86, and the lead sheet 89 are flexible.

For irradiating the subject 50 with radiation 46 in order to capture radiographic images of the subject 50, a preparatory procedure must first be performed for readying the second radiographic apparatus 10B for capturing radiographic images. Such a preparatory procedure includes a process for presetting a source-to-image distance (SID), which represents an distance (imaging distance) between the focus point 122 of the radiation source 44 and a position 124 (see FIG. 44) on the radiation detector 86 that lies straight below the focus point 122, and a process for bringing the central position 126 of the irradiated surface 20 of the detecting screen 250 into alignment with the center of a range within which the irradiated surface 20 is irradiated with radiation 46.

The preparatory procedure is carried out as follows. As shown in FIGS. 43 through 45, while the radiation source device 18 is separated from the cassette 12, the operator 38 pulls the ribbon 76 from the tape measure 72 until the length of the ribbon 76, which is reeled out from the tape measure 72, becomes equal to the reeled-out length 11 depending on the SID. The laser pointer 104 is controlled by the radiation source controller 102 in order to apply a laser beam 128 to the irradiated surface 20, thereby displaying a crisscross mark 130 on the irradiated surface 20, which represents the center of a range within which the irradiated surface 20 is irradiated with radiation 46.

The operator 38 determines the central position 126 of the irradiated surface 20 by observing the gradations 262 thereon. The SID, the reeled-out length 11 depending on the SID, and a distance 12 between the position 124 or the central position 126 and the side 14 a having the hole 80 through which the ribbon 76 is pulled out, are related to each other according to the equation SID≈(11²−12²)^(1/2).

After the ribbon 76 has been pulled from the tape measure 72 by the reeled-out length 11, the operator 38 adjusts the position of the radiation source device 18 so as to bring the mark 130 displayed on the irradiated surface 20 into alignment with the central position 126. Thereafter, the operator 38 turns on the exposure switch 48 in order to enable the radiation source 44 to apply radiation 46 with respect to the subject 50 on the irradiated surface 20, thereby capturing radiographic images of the subject 50, as shown in FIG. 46. In FIG. 46, an example is shown in which a radiographic image of a hand of the subject 50 is captured.

The second mobile apparatus 1000B also operates according to the operation sequences shown in FIGS. 26 through 32. The second mobile apparatus 1000B is operated according to a preparatory procedure and an image capturing process as follows.

First, the operator 38 performs operations to ready the second radiographic apparatus 10B for capturing radiographic images at a site where the second mobile apparatus 1000B has been carried. The operator 38 operates the operating unit 40 of the mobile terminal 42 (or the operating unit 1008 of the console 1004) in order to register image capturing conditions, including subject information (e.g., SID) of the subject 50 to be imaged. The operator 38 pulls the weight bar 252 in order to draw or extend the detecting screen 250 from the storage box 256 by a given length (drawn-out length 13), which is required to capture radiographic images of a region of the subject 50 to be imaged. The rotary encoder 258 detects the drawn-out length 13 of the detecting screen 250, and sends a signal representative of the detected drawn-out length 13 to the SID determining unit 168.

If the unlocking button 34 is pressed by the operator 38, the hook 64 and the slide 56 are displaced against the resiliency of the spring 60 and along the side wall 52 a toward the side wall 52 d, thereby bringing the hook 64 out of engagement with the edge of the through hole 66.

While the hook 64 is kept out of engagement with the edge of the through hole 66, i.e., while the operator 38 presses the unlocking button 34, the operator 38 removes or separates the radiation source device 18 from the cassette 12. The connection terminal 68 a becomes disengaged from the connection terminal 70 a, and the connection terminal 68 b becomes disengaged from the connection terminal 70 b, thereby releasing the radiation source device 18 and the cassette 12 from each other. The radiation source device 18, which is released from the cassette 12, is attached to a distal end 1006 a of an arm unit 1006.

Then, the operator 38 sets the imaging distance and brings the mark 130, which is displayed on the irradiated surface 20, into alignment with the central position 126. Thereafter, the operator 38 places and positions the subject 50 between the irradiated surface 20 and the radiation source device 18. The operator 38 moves the radiation source device 18 in order to reel out the ribbon 76 from the tape measure 72, until the actual reeled-out length of the ribbon 76 reaches the reeled-out length 11 depending on the SID.

After having adjusted the position of the radiation source device 18 until the mark 130 and the central position 126 are aligned with each other, the operator 38 places or positions the subject 50 on the irradiated surface 20, so that the center of a region of the subject 50 to be imaged is aligned with the central position 126, i.e., the position of the mark 130.

After the above positional adjustment has been carried out, the radiation source device 18 is secured to the adjusted position by a holder, not shown, for example.

After the subject 50 is positioned, the operator 38 turns on the exposure switch 48 in order to start capturing radiographic images of the subject 50.

The second mobile apparatus 1000B offers the same advantages as the first mobile apparatus 1000A.

In a case where the second mobile apparatus 1000B is moved, the radiation source device 18 and the cassette 12 of the second radiographic apparatus 10B are housed in the slot 1036 of the second mobile apparatus 1000B, in the state in which the radiation source device 18 and the cassette 12 are integrally joined to each other by the joining mechanism 82. Thus, the radiation source device 18 and the cassette 12 are prevented from falling down even in a case where the second mobile apparatus 1000B moves. Further, since it is unnecessary to hold the radiation source device 18 and the like by hand while the first mobile apparatus 1000A is moving, the second mobile apparatus 1000B can be moved easily and smoothly. For capturing radiographic images, the second radiographic apparatus 10B is taken out from the slot 1036 of the second mobile apparatus 1000B. After the radiation source device 18 and the cassette 12 are separated from each other, the radiation source device 18 may be attached to the distal end 1006 a of the arm unit 1006. Also, after the detecting screen 250 is drawn out or extended from the cassette 12, the detecting screen 250 may be disposed in confronting relation to the radiation source device 18. Thus, the second mobile apparatus 1000B can simply and quickly be readied for capturing radiographic images.

The storage box 256, which is disposed in the cassette 12, accommodates therein the detecting screen 250 in a rolled-up form, so as to be flexible and capable of being extended in sheet form. In a case where the second radiographic apparatus 10B is housed in the second mobile apparatus 1000B, the detecting screen 250 is stored in a rolled-up form inside the storage box 256. In a case where the second radiographic apparatus 10B is operated to capture radiographic images, the detecting screen 250 is drawn out from the storage box 256 in a flat sheet form. Therefore, each of the second radiographic apparatus 10B and the second mobile apparatus 1000B is small in overall size.

For example, if the number of the first radiographic apparatus 10A accommodated in the first mobile apparatus 1000A is equal to the number of the second radiographic apparatus 10B accommodated in the second mobile apparatus 1000B, the size of the second mobile apparatus 1000B can be smaller than the size of the first mobile apparatus 1000A. Also, if the size of the first mobile apparatus 1000A is equal to the size of the second mobile apparatus 1000B, the number of the second radiographic apparatus 10B accommodated in the second mobile apparatus 1000B can be greater than the number of the first radiographic apparatus 10A accommodated in the first mobile apparatus 1000A.

In the first mobile apparatus 1000A, it may be possible to use both of the first radiographic apparatus 10A and the second radiographic apparatus 10B. Also, in the second mobile apparatus 1000B, it may be possible to use both of the second radiographic apparatus 10B and the first radiographic apparatus 10A.

A mobile radiographic image capturing apparatus according to a third embodiment of the present invention, which hereinafter will be referred to as a “third mobile apparatus 1000C,” will be described below with reference to FIGS. 47 through 49.

The third mobile apparatus 1000C essentially is identical in structure to the first mobile apparatus 1000A according to the first embodiment, but differs therefrom in that a cart unit 1002 comprises a first accommodating unit 1050 for accommodating a radiation source device 18, a second accommodating unit 1052 for accommodating cassettes 12, and an image reading apparatus 1054.

The cassette 12 used in the third mobile apparatus 1000C accommodates therein a stimulable phosphor panel 500 (see FIG. 49), which stores radiation energy representative of a radiographic image in a phosphor. In a case where the stimulable phosphor panel 500 is irradiated with stimulating light, the phosphor emits stimulated light representing the stored radiographic image. The radiation source device 18 of the first radiographic apparatus 10A or the second radiographic apparatus 10B is used in the third mobile apparatus 1000C. FIG. 47 shows that the third mobile apparatus 1000C accommodates the three cassettes 12 and the three radiation source device 18, for example.

As shown in FIG. 48, the image reading apparatus 1054 comprises a reader 502 for irradiating the stimulable phosphor panel 500 (see FIG. 49) with stimulating light and reading radiation energy representative of radiographic image information that is stored in the stimulable phosphor panel 500 (see FIG. 49) by radiography, an image memory 504 for storing the radiographic image information read by the reader 502, an image processor 506 for performing an image processing process (including a correcting process) of the radiographic image information stored in the image memory 504, an ID memory 508 for storing the ID of the reading apparatus for identifying the image reading apparatus 1054, an interface 510 (I/F), a transceiver 512 for sending information to and receiving information from an external device (a network, a radiation source device 18, or the like).

The first energy input/output unit 300 or the second energy input/output unit 302 is mounted, for example, on a side wall of the image reading apparatus 1054. The first energy input/output unit 300 of the image reading apparatus 1054 may be connected to the first energy input/output units 300 of the radiation source devices 18 through wired connections, while the second energy input/output unit 302 of the image reading apparatus 1054 may be connected to the first energy input/output units 300 of the radiation source devices 18 through wireless connections.

As shown in FIG. 48, the image reading apparatus 1054 also incorporates therein a battery unit 304 and a battery controller 306 that are similar to those of the radiation source device 18 and the cassette 12. The third mobile apparatus 1000C is also carried (moved) to an accident or disaster site, as well as a patient room in the hospital or a home of a person receiving home-care services. Thus, in the radiation source device 18 and the image reading apparatus 1054, at least a portion surrounding an electric system thereof is often sealed. Therefore, contactless electric power supply through wireless connections or the like is desirable for an electric power supply method, compared to contact electric power supply by wired connections or the like.

As shown in FIG. 49, the image reading apparatus 1054 includes a cassette loader 522 disposed in an upper portion of a casing 520. The cassette loader 522 has a loading slot 524 for receiving the cassette 12, which houses therein the stimulable phosphor panel 500 with recorded radiographic image information. Near the loading slot 524, the casing 520 accommodates therein a bar-code reader 526 for reading identification information recorded in a bar code on the cassette 12, an unlocking mechanism 530 for unlocking a lid 528 of the cassette 12, a suction cup 532 for attracting and removing the stimulable phosphor panel 500 from the cassette 12 in a case where the lid 528 is opened, and a pair of nip rollers 534 for gripping and feeding the stimulable phosphor panel 500 removed by the suction cup 532.

The nip rollers 534 are followed by a plurality of feed rollers 536 a through 536 g and a plurality of guide plates 538 a through 538 f, which jointly make up a curved feed path 540. The curved feed path 540 extends downwardly from the cassette loader 522, extends substantially horizontally at a lowermost portion thereof, and then extends substantially vertically upward. A curved feed path 540 of this shape is effective in making the image reading apparatus 1054 small in size.

An erasing unit 542 is disposed between the nip rollers 534 and the feed rollers 536 a, for erasing radiographic image information remaining in the stimulable phosphor panel 500, from which desired radiographic image information has already been read. The erasing unit 542 has a plurality of erasing light sources 544 such as cold cathode-ray tubes or the like for emitting erasing light.

A platen roller 546 is disposed between the feed rollers 536 d, 536 e, which are positioned in the lowermost portion of the curved feed path 540. The platen roller 546 is disposed beneath a scanning unit 548 for reading desired radiographic image information recorded in the stimulable phosphor panel 500.

The scanning unit 548 comprises a stimulator 550 for emitting a laser beam LB as stimulating light to scan the stimulable phosphor panel 500, and a reader 502 for reading stimulated light emitted from the stimulable phosphor panel 500, which is stimulated by the laser beam LB.

A stimulator 550 comprises a laser oscillator 552 that outputs the laser beam LB, a rotary polygon mirror 554 for deflecting the laser beam LB in a main scanning direction across the stimulable phosphor panel 500, and a reflecting mirror 556 for reflecting the laser beam LB toward the stimulable phosphor panel 500 as the stimulable phosphor panel 500 passes over the platen roller 546.

The reader 502 comprises a light guide 558 having a lower end disposed near the stimulable phosphor panel 500 over the platen roller 546, and a photomultiplier 560 connected to an upper end of the light guide 558, for converting stimulated light from the stimulable phosphor panel 500 into an electric signal, which represents the radiographic image information stored in the stimulable phosphor panel 500. A light collecting mirror 562 for effectively collecting stimulated light from the stimulable phosphor panel 500 is disposed near the lower end of the light guide 558. The radiographic image information read by the photomultiplier 560 is processed in the image processor 506 (including a correcting process) in the image reading apparatus 1054. As shown in FIG. 48, the radiographic image information from the reader 502 is stored in the image memory 504, processed in the image processor 506, and sent to the console 1004 or the data center via the transceiver 512, together with the identification information of the image reading apparatus 1054.

In a case where the radiographic image capturing is performed by the third mobile apparatus 1000C, the radiation source device 18 is taken out from the first accommodating unit 1050 and attached to the distal end 1006 a of the arm unit 1006. The cassette 12 is disposed in confronting relation to the radiation source device 18, while the subject 50 is interposed therebetween and the irradiated surface 20 faces the radiation source device 18. Then, an image capturing switch is operated for capturing radiographic images.

After the radiographic images are captured, the cassette 12 is inserted into the image reading apparatus 1054. The radiographic image information stored in the stimulable phosphor panel 500 in the cassette 12 is read and stored in the image memory 504 (see FIG. 48). In this case, also, the radiographic image information is sent to the console 1004 or the data center via the transceiver 512.

The third mobile apparatus 1000C is controlled so as to supply electric power from the radiation source device 18 to the image reading apparatus 1054, or from the image reading apparatus 1054 to the radiation source device 18. In other words, the operation of the third mobile apparatus 1000C can be explained in the same manner as that of the first mobile apparatus 1000A or the second mobile apparatus 1000B, if the image reading apparatus 1054 serves as the source and destination of electric power. Thus, the electric power controller 334 of the third mobile apparatus 1000C basically has a configuration similar to the configuration shown in FIG. 21 (first specific example) or shown in FIG. 22 (second specific example), and operation sequences similar to the sequences shown in FIGS. 26 through 32. The third mobile apparatus 1000C, however, does not incorporate therein the functional components relating to the cassette 12, i.e., any of a cassette selector activator 362, a cassette selector 364, an integrated supply activator 366, and an integrated supply 368. Thus, in the operation sequence shown in FIG. 26, steps S3 and S4 (which relate to the selection of a cassette) and steps S5 and S6 (which relate to integrated supply) are not performed.

In the third mobile apparatus 1000C as well, since the console 1004 can supply electric power to respective devices, it is possible to set a supply route from the console 1004 to a radiation source device 18 that is used to capture radiographic images, as well as a supply route from the console 1004 to an image reading apparatus 1054. It also is possible to set a supply route from the console 1004 as a supply source to the aforesaid radiation source device 18, as well as a supply route from the console 1004 as a supply source to the aforesaid image reading apparatus 1054. Furthermore, it is possible to set a supply route from the aforesaid radiation source device 18 via the console 1004 to the aforesaid image reading apparatus 1054, as well as a supply route from the aforesaid image reading apparatus 1054 via the console 1004 to the aforesaid radiation source device 18.

Since electric power can be supplied from the console 1004 to the radiation source device 18 and the image reading apparatus 1054, or electric power can be supplied between the radiation source device 18 and the image reading apparatus 1054 via the console 1004, the console 1004 can perform a centralized electric power management process for efficiently supplying electric power between the radiation source device 18 and the image reading apparatus 1054. Inasmuch as electric power can be collected from one or more radiation source devices 18 and the image reading apparatus 1054 into the console 1004, the console 1004 can perform a battery function that enables efficient electric power management, so as to avoid power supply problems such as sudden power supply interruptions in a case where electric power needs to be supplied to the radiation source device 18 and the image reading apparatus 1054.

Since the cassette 12 itself does not have a memory 330, the association between the radiation source device 18 and the cassette 12, which have been used for capturing radiographic images, is provided, e.g., using the console 1004. For example, a bar code (ID information) attached to the cassette 12 is read by the bar-code reader 526, and the console 1004 may associate the read ID information of the cassette 12 with the ID information from the radiation source device 18.

Since the third mobile apparatus 1000C limits a route for supply of electric power, e.g., only the route from the radiation source device 18 to the image reading apparatus 1054, or only the route from the image reading apparatus 1054 to the radiation source device 18. Thus, electric power does not have to be supplied in vain and the third mobile apparatus 1000C can reduce consumption of electric power. Also, the third mobile apparatus 1000C offers the same advantages as the first mobile apparatus 1000A and the second mobile apparatus 1000B.

Although certain preferred embodiments of the present invention have been shown and described in detail, it should be understood that various changes and modifications may be made to the embodiments without departing from the scope of the invention as set forth in the appended claims.

For example, the radiation detector 86 may be a radiation detector 600 according to a modified example shown in FIGS. 50 and 51. FIG. 50 is a cross-sectional view schematically illustrating the structure of three pixel units of the radiation detector 600 according to a modified example of the invention.

As shown in FIG. 50, the radiation detector 600 includes a signal output unit 604, a sensor unit 606 (photoelectric converter), and a scintillator 608 that are sequentially laminated on an insulating substrate 602. The signal output unit 604 and the sensor unit 606 form a pixel unit. Plural pixel units are arranged in a matrix on the substrate 602, such as an array of pixel units arranged in rows and columns. In each pixel unit, the signal output unit 604 and the sensor unit 606 are arranged so as to overlap each other.

The scintillator 608 is formed on the sensor unit 606 with a transparent insulating film 610 interposed therebetween, and has a phosphor film that converts radiation 46 incident from the upper side (the side opposite to the substrate 602) into light and emits the light. It is preferable that the wavelength range of light emitted by the scintillator 608 be a visible light range (wavelength of 360 nm to 830 nm). It is more preferable that the wavelength range of light include a green wavelength range in order to capture a monochromatic image using the radiation detector 600.

Specifically, in a case in which imaging is performed using X-rays as radiation 46, it is preferable that the phosphor used for the scintillator 608 include cesium iodide (CsI). It is more preferable to use CsI(Tl) (thallium-added cesium iodide) having an emission spectrum of 420 nm to 700 nm during the emission of X-rays. The emission peak wavelength of CsI(Tl) in the visible light range is 565 nm.

The scintillator 608, for example, may be formed on a vapor deposition substrate by vapor deposition of a columnar crystal of CsI(Tl). As such, in a case in which the scintillator 608 is formed by vapor deposition, an Al plate is generally used as the vapor deposition substrate in terms of the transmittance of X-rays and manufacturing costs, but the vapor deposition substrate is not limited to the Al plate. In a case in which GOS is used as the scintillator 608, GOS may be applied onto the surface of a TFT active matrix substrate to form the scintillator 608, without using the vapor deposition substrate. Alternatively, after the scintillator 608 is formed by applying GOS to a resin base, the scintillator 608 may be attached to a TFT active matrix substrate. In this case, even if the application of GOS failed, the TFT active matrix substrate would not be damaged.

The sensor unit 606 includes an upper electrode 612, a lower electrode 614, and a photoelectric conversion film 616 provided between the upper and lower electrodes 612, 614.

The upper electrode 612 needs to make light generated by the scintillator 608 incident on the photoelectric conversion film 616. Therefore, it is preferable that the upper electrode 612 be made of a conductive material that is at least transparent with respect to the emission wavelength of the scintillator 608. Specifically, it is preferable that the upper electrode 612 be made of a transparent conducting oxide (TCO) having high transmittance with respect to visible light and a small resistance value. A metal thin film, such as an Au thin film, may be used as the upper electrode 612. However, if the transmittance increases to 90% or more, the resistance value is likely to increase. Therefore, it is preferable that the upper electrode 612 be made of TCO. For example, it is preferable that the upper electrode 612 be made of ITO, IZO, AZO, FTO, SnO₂, TiO₂, ZnO₂, etc. It is most preferable that the upper electrode 612 be made of ITO in terms of a simple process, low resistance, and transparency. One upper electrode 612 may be common to all pixel units, or the upper electrode 612 may be divided for each pixel unit.

The photoelectric conversion film 616 includes an organic photoconductor (OPC) and absorbs light emitted from the scintillator 608 and generates a charge corresponding to the absorbed light. If the photoelectric conversion film 616 includes an organic photoconductor (an organic photoelectric conversion material), it has a narrow absorption spectrum in the visible light range and absorbs little electromagnetic waves other than the light emitted from the scintillator 608. Therefore, it is possible to effectively reduce noise generated due to the absorption of radiation 46 by the photoelectric conversion film 616. For example, the photoelectric conversion film 616 may include amorphous silicon instead of an organic photoconductor. If the photoelectric conversion film 616 includes amorphous silicon, it has a wide absorption spectrum and can absorb light emitted from the scintillator 608 efficiently.

It is preferable that the absorption peak wavelength of the organic photoconductor forming the photoelectric conversion film 616 be close to the emission peak wavelength of the scintillator 608 in order to most effectively absorb light emitted from the scintillator 608. It is ideal that the absorption peak wavelength of the organic photoconductor is equal to the emission peak wavelength of the scintillator 608. However, if the difference between the absorption peak wavelength and the emission peak wavelength is small, it is possible to sufficiently absorb light emitted from the scintillator 608. Specifically, the difference between the absorption peak wavelength of the organic photoconductor and the emission peak wavelength of the scintillator 608 with respect to the radiation 46 is preferably equal to or less than 10 nm and more preferably, equal to or less than 5 nm.

Examples of the organic photoconductor capable of satisfying the above-mentioned conditions include a quinacridone-based organic compound and a phthalocyanine-based organic compound. For example, the absorption peak wavelength of quinacridone in the visible light range is 560 nm. Therefore, if quinacridone is used as the organic photoconductor and CsI(Tl) is used as the material forming the scintillator 608, it is possible to reduce the difference between the peak wavelengths to 5 nm or less and substantially maximize the amount of charge generated by the photoelectric conversion film 616.

The sensor unit 606 includes an organic layer that is formed by laminating or mixing, for example, an electromagnetic wave absorption portion, a photoelectric conversion portion, an electron transport portion, a hole transport portion, an electron blocking portion, a hole blocking portion, a crystallization prevention portion, an electrode, and an interlayer contact improvement portion. It is preferable that the organic layer include an organic p-type compound (organic p-type semiconductor) or an organic n-type compound (organic n-type semiconductor).

The organic p-type semiconductor is a donor-type organic semiconductor (compound) whose representative example is a hole-transport-type organic compound and means an organic compound which readily donates electrons. Specifically, in a case in which two organic materials are in contact with each other during use, one organic compound with low ionization potential is the organic p-type semiconductor. Therefore, any organic compound may be used as the donor-type organic compound as long as it has an electron donating property.

The organic n-type semiconductor is an acceptor-type organic semiconductor (compound) whose representative example is an electron-transport-type organic compound and means an organic compound which readily accepts electrons. Specifically, in a case in which two organic compounds are in contact with each other during use, one organic compound with high electron affinity is the organic n-type semiconductor. Therefore, any organic compound may be used as the acceptor-type organic compound as long as it has an electron accepting property.

Materials applicable to the organic p-type semiconductor and the organic n-type semiconductor and the structure of the photoelectric conversion film 616 have been described in detail in Japanese Laid-Open Patent Publication No. 2009-032854 and thus a detailed description thereof will be omitted. The photoelectric conversion film 616 may include fullerene or carbon nanotubes.

It is preferable that the thickness of the photoelectric conversion film 616 be as large as possible in terms of the absorption of light from the scintillator 608. However, if the thickness of the photoelectric conversion film 616 is greater than a predetermined value, the intensity of the electric field of the photoelectric conversion film 616 generated by the bias voltage applied from both ends of the photoelectric conversion film 616 is reduced, which makes it difficult to collect charge. Therefore, the thickness of the photoelectric conversion film 616 is preferably from 30 nm to 300 nm, more preferably from 50 nm to 250 nm, and most preferably from 80 nm to 200 nm.

One photoelectric conversion film 616 is common to all pixel units. However, the photoelectric conversion film 616 may be divided for each pixel unit. The lower electrode 614 is a thin film that is divided for each pixel unit. However, one lower electrode 614 may be common to all pixel units. The lower electrode 614 may be appropriately made of a transparent or opaque conductive material, such as aluminum or silver. The thickness of the lower electrode 614 may be, for example, from 30 nm to 300 nm.

In the sensor unit 606, a predetermined bias voltage can be applied between the upper electrode 612 and the lower electrode 614 to move one of the charges (a hole and an electron) generated from the photoelectric conversion film 616 to the upper electrode 612 and move the other charge to the lower electrode 614. In the radiation detector 600 according to this modified example, a wiring line is connected to the upper electrode 612 and the bias voltage is applied to the upper electrode 612 through the wiring line. It is assumed that the polarity of the bias voltage is determined such that the electron generated in the photoelectric conversion film 616 is moved to the upper electrode 612 and the hole is moved to the lower electrode 614. However, the polarity may be reversed.

The sensor unit 606 forming each pixel unit may include at least the lower electrode 614, the photoelectric conversion film 616, and the upper electrode 612. In order to prevent an increase in dark current, it is preferable that at least one of electron blocking film 618 and hole blocking film 620 be provided, and it is more preferable that both the electron blocking film 618 and the hole blocking film 620 be provided.

The electron blocking film 618 may be provided between the lower electrode 614 and the photoelectric conversion film 616. In a case in which the bias voltage is applied between the lower electrode 614 and the upper electrode 612, it is possible to prevent an increase in the dark current due to the injection of electrons from the lower electrode 614 into the photoelectric conversion film 616.

The electron blocking film 618 may be made of an electron donating organic material. In practice, the material used for the electron blocking film 618 may be selected according to a material forming an adjacent electrode and a material forming an adjacent photoelectric conversion film 616. It is preferable that the material used for the electron blocking film 618 have an electron affinity (Ea) that is at least 1.3 eV higher than the work function (Wf) of the material forming the adjacent electrode and have an ionization potential (Ip) equal to or less than that of the material forming the adjacent photoelectric conversion film 616. Materials applicable as the electron donating organic material have been described in detail in Japanese Laid-Open Patent Publication No. 2009-032854 and thus a detailed description thereof will be omitted.

The thickness of the electron blocking film 618 is preferably from 10 nm to 200 nm, more preferably from 30 nm to 150 nm, and most preferably from 50 nm to 100 nm in order to reliably obtain the effect of preventing the dark current and prevent a reduction in the photoelectric conversion efficiency of the sensor unit 606.

The hole blocking film 620 may be provided between the photoelectric conversion film 616 and the upper electrode 612. In a case in which the bias voltage is applied between the lower electrode 614 and the upper electrode 612, it is possible to prevent an increase in the dark current due to the injection of holes from the upper electrode 612 into the photoelectric conversion film 616.

The hole blocking film 620 may be made of an electron accepting organic material. The thickness of the hole blocking film 620 is preferably from 10 nm to 200 nm, more preferably from 30 nm to 150 nm, and most preferably from 50 nm to 100 nm in order to reliably obtain the effect of preventing the dark current and prevent a reduction in the photoelectric conversion efficiency of the sensor unit 606.

In practice, the material used for the hole blocking film 620 may be selected according to a material forming an adjacent electrode and a material forming an adjacent photoelectric conversion film 616. It is preferable that the material used for the hole blocking film 620 have an ionization potential (Ip) that is at least 1.3 eV higher than the work function (Wf) of the material forming the adjacent electrode and have an electron affinity (Ea) equal to or more than that of the material forming the adjacent photoelectric conversion film 616. Materials applicable as the electron accepting organic material have been described in detail in Japanese Laid-Open Patent Publication No. 2009-032854 and thus a detailed description thereof will be omitted.

In a case in which the bias voltage is set such that, among the charges generated in the photoelectric conversion film 616, holes are moved to the upper electrode 612 and electrons are moved to the lower electrode 614, the positions of the electron blocking film 618 and the hole blocking film 620 may be reversed. In addition, it is not necessary to provide both the electron blocking film 618 and the hole blocking film 620. If either the electron blocking film 618 or the hole blocking film 620 is provided, it is possible to a certain extent to obtain the effect of preventing the dark current.

As shown in FIG. 51, the signal output unit 604 is provided on the surface of the substrate 602 so as to correspond to the lower electrode 614 of each pixel unit. The signal output unit 604 has a storage capacitor 622 that stores the charge moved to the lower electrode 614, and a TFT 624 that converts the charge stored in the storage capacitor 622 into an electric signal and outputs the electric signal. A region in which the storage capacitor 622 and the TFT 624 are formed has a portion that overlaps the lower electrode 614 in a plan view. In this way, the signal output unit 604 and the sensor unit 606 in each pixel unit overlap each other in the thickness direction. It is possible to minimize the plane area of the radiation detector 600 (pixel unit), if the signal output unit 604 is formed such that the storage capacitor 622 and the TFT 624 are completely covered with the lower electrode 614.

The storage capacitor 622 is electrically connected to the corresponding lower electrode 614 through a conductive line that is formed so as to pass through an insulating film 626 provided between the substrate 602 and the lower electrode 614. In this way, it is possible to move the charge captured by the lower electrode 614 to the storage capacitor 622.

The TFT 624 is formed by laminating a gate electrode 628, a gate insulating film 630, and an active layer (channel layer) 632 and providing a source electrode 634 and a drain electrode 636 on the active layer 632 with a predetermined gap therebetween. The active layer 632 may be made of, for example, amorphous silicon, an amorphous oxide, an organic semiconductor material, or carbon nanotubes. The material forming the active layer 632 is not limited thereto.

An oxide (for example, an In—O-based oxide) including at least one of In, Ga, and Zn is preferable as the amorphous oxide that can form the active layer 632. An oxide (for example, an In—Zn—O-based oxide, an In—Ga—O-based oxide, or a Ga—Zn—O-based oxide) including at least two of In, Ga, and Zn is more preferable as the amorphous oxide. An oxide including In, Ga, and Zn is most preferable as the amorphous oxide. As an In—Ga—Zn—O-based amorphous oxide, an amorphous oxide having a composition represented by InGaO₃(ZnO)_(m) (m is a natural number smaller than 6) in a crystalline state is preferable, and InGaZnO₄ is more preferable. The amorphous oxide that can form the active layer 632 is not limited thereto.

A phthalocyanine compound, pentacene, or vanadyl phthalocyanine may be given as an example of the organic semiconductor material that can form the active layer 632, but the organic semiconductor material is not limited thereto. The structure of the phthalocyanine compound has been described in detail in Japanese Laid-Open Patent Publication No. 2009-212389 and thus a detailed description thereof will be omitted.

If the active layer 632 of the TFT 624 is made of an amorphous oxide, an organic semiconductor material, or carbon nanotubes, radiation 46, such as X-rays, is not absorbed. Even if the radiation 46 is absorbed, the absorbed amount will be very small. Therefore, it is possible to effectively prevent the generation of noise in the signal output unit 604.

In a case in which the active layer 632 is made of carbon nanotubes, it is possible to improve the switching speed of the TFT 624 and form the TFT 624 with low light absorptance in the visible light range. In addition, in a case in which the active layer 632 is made of carbon nanotubes, even though a very small amount of metallic impurities is mixed with the active layer 632, the performance of the TFT 624 is significantly reduced. Therefore, it is necessary to separate and extract carbon nanotubes with very high purity using, for example, centrifugal separation and form the active layer 632 with the carbon nanotubes.

All of the amorphous oxide, the organic semiconductor material, the carbon nanotubes, and the organic photoconductor can be used to form a film at a low temperature. Thus, the substrate 602 is not limited to a substrate with high heat resistance, such as a semiconductor substrate, a quartz substrate, or a glass substrate, but a flexible substrate, such as a plastic substrate, an aramid substrate, or a bio-nanofiber substrate may be used as the substrate 602. Specifically, for example, a flexible substrate made of the following materials may be used: polyester, such as polyethylene terephthalate, polybutylene phthalate, or polyethylene naphthalate, polystyrene, polycarbonate, polyether sulfone, polyarylate, polyimide, polycycloolefin, norbornene resin, and polychlorotrifluoroethylene. If such a flexible substrate made of plastic is used, it is possible to reduce the weight of the substrate. For example, this structure has an advantage in portability.

If the photoelectric conversion film 616 is formed of the organic photoconductor and the TFT 624 is formed of the organic semiconductor material, it is possible to form films of the photoelectric conversion film 616 and the TFT 624 at a low temperature with respect to a flexible substrate (substrate 602) of plastic. Also, it is possible to reduce the thickness and weight of the radiation detector 600 in its entirety, and thereby it is possible to reduce the thickness and weight of the cassette 12 housing the radiation detector 600. Accordingly, it is possible to improve convenience if used outside of a hospital. Further, a base material of the photoelectric conversion unit is made of a flexible material instead of glass that is commonly used. Thus, it is possible to enhance resistance to damage or the like if the radiographic image capturing apparatus is carried or used.

In addition, for example, an insulating layer for ensuring an insulating property, a gas barrier layer for preventing the penetration of water or oxygen, and an undercoating layer for improving flatness or the adhesion of, for example, the electrode may be provided on the substrate 602.

Since aramid can be applied to a high-temperature process of 200 degrees or more, a transparent electrode material can be cured at a high temperature to have low resistance, and the aramid can respond to the automatic mounting of a driver IC including a solder reflow process. In addition, the thermal expansion coefficient of aramid is close to that of ITO (indium tin oxide) or a glass substrate. Therefore, after an aramid substrate is manufactured, the warping of the aramid substrate is small and the aramid substrate is less likely to be cracked. In addition, aramid is capable of forming a substrate thinner than, for example, a glass substrate. Aramid may be laminated on a super-thin glass substrate to form the substrate 602.

The bio-nanofiber is a composite of a cellulose microfibril bundle (bacterial cellulose) generated by bacteria (Acetobacter, Acetobacter Xylinum) and a transparent resin. The cellulose microfibril bundle has a width of 50 nm, a size of one-tenth of the visible light wavelength, high strength, high elasticity, and a low thermal expansion coefficient. A transparent resin, such as an acrylic resin or an epoxy resin, is impregnated into the bacterial cellulose and is then cured to obtain bio-nanofiber that has a light transmittance of about 90% at a wavelength of 500 nm while including 60 to 70% of fiber. The bio-nanofiber has a low thermal expansion coefficient (3 to 7 ppm) equal to that of a silicon crystal, strength (460 MPa) similar to that of steel, high elasticity (30 GPa), and flexibility. Therefore, the bio-nanofiber is capable of forming a substrate 602 thinner than, for example, a glass substrate.

In this example, the signal output unit 604, the sensor unit 606, and the transparent insulating film 610 are sequentially formed on the substrate 602 and the scintillator 608 is bonded to the substrate 602 by an adhesive resin with low light absorptance, thereby forming the radiation detector 600.

In the radiation detector 600 according to the modified example, since the photoelectric conversion film 616 is made of an organic photoconductor and the active layer 632 of the TFT 624 is made of the organic semiconductor material, radiation 46 is hardly absorbed by the photoelectric conversion film 616 or the signal output unit 604. Therefore, it is possible to prevent a reduction in sensitivity for the radiation 46.

Both the organic semiconductor material forming the active layer 632 of the TFT 624 and the organic photoconductor forming the photoelectric conversion film 616 can be used to form a film at a low temperature. Therefore, the substrate 602 can be made of a plastic resin, aramid, or bio-nanofiber that absorbs a small amount of radiation 46. Accordingly, it is possible to prevent a reduction in sensitivity for the radiation 46.

For example, in a case in which the radiation detector 600 is adhered to the irradiated surface 20 of the housing and the substrate 602 is made of a plastic resin with high rigidity, aramid, or bio-nanofiber, it is possible to reduce the thickness of the irradiated surface 20 of the housing since the radiation detector 600 has high rigidity. In addition, in a case in which the substrate 602 is made of a plastic resin, aramid, or bio-nanofiber having high rigidity, the radiation detector 600 has flexibility. In a case where the substrate 602 is made of a plastic resin, aramid, or bio-nanofiber having high rigidity, even if an impact is applied to the irradiated surface 20, the radiation detector 600 is less likely to be damaged due to its flexibility.

The radiation detector 600 may be configured as follows.

(1) The photoelectric conversion film 616 may be made of an organic photoelectric conversion material, for forming a TFT layer 638 using CMOS sensors. In this case, since only the photoelectric conversion film 616 is made of the organic material, the TFT layer 638 including the CMOS sensors does not have to be flexible.

(2) A flexible TFT layer 638 may be formed by the photoelectric conversion film 616 made of an organic photoelectric conversion material, and by CMOS circuits including TFTs 624 made of the organic material. In this case, pentacene may preferably be used as the material of the organic p-type semiconductor used for the CMOS circuits, and fluorinated copper phthalocyanine (F₁₆CuPc) may preferably be used as the material of the organic n-type semiconductor. Then, it is possible to form a flexible TFT layer 638 having a smaller bend radius. With such a TFT layer 638, it is possible to make the gate insulating film thinner significantly, so that the drive voltage can be lower. Further, a gate insulating film, a semiconductor, each electrode can be made at room temperature or at a temperature of 100° C. or lower. Furthermore, CMOS circuits can be fabricated directly on the flexible substrate 602. Also, an organic TFT 624 can be miniaturized using a production process according to the scaling law. In forming the substrate 602, if a polyimide precursor is applied to a thin polyimide substrate by a spin coat method and heated, a flat substrate without irregularities can be formed since the polyimide precursor is changed to polyimide.

(3) The Fluidic Self-Assembly technology, which enables a plurality of micron-scale device blocks to be assembled in designated positions on the substrate 602, may be adopted for aligning the photoelectric conversion film 616 of crystal Si and the TFTs 624 on the resin substrate 602. In this case, the photoelectric conversion film 616 and the TFTs 624 as micron-scale device blocks are fabricated on another substrate, and separated from the substrate. In a liquid, the photoelectric conversion film 616 and the TFTs 624 are suspended and assembled statistically on the target substrate 602. Since the substrate 602 is processed beforehand for matching the device blocks, the device blocks can be selectively assembled on the target substrate 602. Accordingly, optimum device blocks (photoelectric conversion film 616 and TFTs 624) made of optimum material can be integrated on an optimum substrate (a semiconductor substrate, a quartz substrate, or a glass substrate). Further, optimum device blocks (photoelectric conversion film 616 and TFTs 624) can be integrated on a noncrystalline substrate (flexible substrate made of plastics or the like).

The radiation detector 600 according to the modified example is a so-called rear surface reading type (so-called PSS (Penetration Side Sampling) type) in which the light emitted from the scintillator 608 is converted by the sensor unit 606 (photoelectric conversion film 616) into the electric charge for reading the radiographic image, while the sensor unit 606 is positioned on the side opposite to the radiation source 44. The type of the radiation detector, however, is not limited thereto.

For example, a radiation detector may be a so-called front surface reading type (so-called ISS (Irradiation Side Sampling) type). In this case, the insulating substrate 602, the signal output unit 604, the sensor unit 606, and the scintillator 608 are successively laminated along an irradiation direction of the radiation 46. The light emitted from the scintillator 608 is converted by the sensor unit 606 into the electric charge for reading the radiographic image, while the sensor unit 606 is positioned on the same side as the radiation source 44. Usually, the scintillator 608 emits light having higher intensity on a radiation-irradiated side by the radiation 46 than a back side. Therefore, in the radiation detector of the front surface reading type, the distance from the scintillator 608 to the photoelectric conversion film 616, by which emitted light travels, can be shorter than in the radiation detector 600 of the rear surface reading type. Thus, it is possible to reduce the diffusion or attenuation of the light. As a result, the resolution of the radiographic image can be higher. 

1.-28. (canceled)
 29. A radiographic image capturing apparatus comprising: a mobile cart unit; a plurality of devices used for capturing a radiographic image; an electric power supply activator enabling supply of electric power between the devices, based on an instruction of permission to supply electric power; an electric power manager activatable by the electric power supply activator, based on the instruction of permission to supply electric power, wherein the devices at least comprise: a radiation source device including a radiation source for outputting radiation; and a detector device detachably attached to the cart unit, and including a radiation detector for detecting radiation that is transmitted through a subject in a case where the subject is irradiated with the radiation by the radiation source, and converting the detected radiation into radiographic image information, and wherein the electric power manager includes an amount-of-consumed-electric-power predictor that calculates and predicts amounts of electric power consumption used to capture radiographic images by each of the radiation source device and the detector device, the electric power manager, based on the electric power consumption predicted by the amount-of-consumed-electric-power predictor, manages electric power required to capture a given number of radiographic images, and supplies at least part of the required electric power flexibly to at least one of the radiation source device and the detector device.
 30. The radiographic image capturing apparatus according to claim 29, wherein the amount-of-consumed-electric-power predictor calculates and predicts, from battery charging conditions and present or previous image capturing conditions, amounts of electric power consumption used to capture radiographic images by each of the radiation source device and the detector device.
 31. The radiographic image capturing apparatus according to claim 29, wherein the amount-of-consumed-electric-power predictor calculates and predicts, from battery charging conditions, present or previous image capturing conditions, and usage history, amounts of electric power consumption used to capture radiographic images by each of the radiation source device and the detector device.
 32. The radiographic image capturing apparatus according to claim 31, wherein the amount-of-consumed-electric-power predictor calculates, from battery charging conditions and present or previous image capturing conditions, amounts of electric power consumption used to capture radiographic images by each of the radiation source device and the detector device, and corrects each amount of electric power consumption by multiplying coefficients corresponding to the number of times that each of the radiation source device and the detector device has been used.
 33. A method for a radiographic image capturing apparatus including: a mobile cart unit, a plurality of devices used for capturing a radiographic image, and an electric power supply activator enabling supply of electric power between the devices, based on an instruction of permission to supply electric power, wherein the devices at least comprise: a radiation source device including a radiation source for outputting radiation; and a detector device detachably attached to the cart unit, and including a radiation detector for detecting radiation that is transmitted through a subject in a case where the subject is irradiated with the radiation by the radiation source, and converting the radiographic image information, the method comprising: predicting amounts of electric power consumption used to capture radiographic images by each of the radiation source device and the detector device, based on an instruction of permission to supply electric power; managing electric power required to capture a given number of radiographic images; and supplying at least part of the required electric power flexibly to at least one of the radiation source device and the detector device.
 34. The method according to claim 33, wherein predicting the amounts of electric power consumption includes calculating and predicting, from battery charging conditions and present or previous image capturing conditions, amounts of electric power consumption used to capture radiographic images by each of the radiation source device and the detector device.
 35. The method according to claim 33, wherein predicting the amounts of electric power consumption includes calculating and predicting, from battery charging conditions, present or previous image capturing conditions, and usage history, amounts of electric power consumption used to capture radiographic images by each of the radiation source device and the detector device.
 36. The method according to claim 35, wherein predicting the amounts of electric power consumption includes: calculating, from battery charging conditions and present or previous image capturing conditions, amounts of electric power consumption used to capture radiographic images by each of the radiation source device and the detector device, and correcting each amount of electric power consumption by multiplying coefficients corresponding to the number of times that each of the radiation source device and the detector device has been used. 